KR102263802B1 - Classifier cyclone for desulfurization system and manufacturing method - Google Patents

Abstract

The present invention relates to a classifier cyclone for desulfurization facility of a thermal power generation system and a method for manufacturing the same. The present invention proposes a classifier cyclone for desulfurization facility of a thermal power generation system and a method for manufacturing the same, wherein a double structure having a ceramic inner material and a resin outer material is manufactured by using insert injection for each of the components consisting of a vortex finder, an inlet head, a cone, and a nozzle as a body having a through hollow. Thus, it is possible to ensure durability for a part in contact with limestone slurry while reducing the overall weight to pursue for weight reduction, thereby being able to enhance the convenience of use, such as facilitating assembly or disassembly by a single operator.

Description

Classifier cyclone for desulfurization equipment of thermal power generation system and its manufacturing method {CLASSIFIER CYCLONE FOR DESULFURIZATION SYSTEM AND MANUFACTURING METHOD}

The present invention relates to a classifier cyclone for desulfurization equipment installed and used in a thermal power generation system and a method for manufacturing the same, and more particularly, to limestone by providing component parts with a ceramic material and coating the outer surface with a resin skin material by insert injection method. Classifier cyclone for desulfurization equipment of thermal power generation system, which enables to reduce overall weight while securing durability for the part in contact with slurry, and to improve ease of use by facilitating assembly or disassembly by a single operator; It relates to a manufacturing method thereof.

In general, a thermal power plant generates electricity by using thermal energy obtained by burning fuel such as petroleum or coal, and when the fuel is burned, a lot of sulfur components, which are harmful substances, are generated.

Accordingly, it is stipulated that thermal power plants must be equipped with a desulfurization facility for an eco-friendly process. This desulfurization facility is a device for removing sulfur components generated during the process of burning fuel in a thermal power plant, and recently wet desulfurization. As one of the methods, a technique for removing sulfur using limestone slurry is widely applied.

In other words, as a conventional desulfurization facility used to remove sulfur using limestone slurry, a cyclone (1), which is one of the separation devices, is applied as in the example of FIG. 1, and the limestone slurry is converted into a cyclone (1). It is dropped by putting it into the inside, but the slurry with a heavy specific gravity falls down the body as it is, and the fine particles with a light specific gravity rises up and separates from each other.

At this time, limestone fine particles having a light specific gravity are transported through the transport pipe 2 while rising above the body of the cyclone 1 and used to absorb sulfur generated during combustion, and the specific gravity falling below the body of the cyclone 1 This heavy limestone slurry is sent to a ball mill (not shown) provided as a lower part of the cyclone 1 , and is configured to be pulverized and then reintroduced into the cyclone 1 .

In this way, the conventional cyclone equipment used to remove sulfur using the limestone slurry is manufactured from a polyurethane material in order to reduce the wear of the cyclone according to the input of the limestone slurry.

However, conventional cyclones for desulfurization facilities in thermal power plants have been made of polyurethane material to reduce wear, but they do not produce satisfactory results for wear resistance, as well as severe wear due to frequent contact due to the input of limestone slurry. There was a problem that the facility was messy due to the cyclone bursting and the limestone slurry leaking outside. This shortened the lifespan of the cyclone, caused the inconvenience of frequent replacement and frequent washing, and it was difficult to manage and not economical, etc. Many problems are occurring.

In addition, in order to solve this problem, it is manufactured and used with a stainless material, but the manufacturing cost is high and the weight is significant due to the application of only a metal material, so there is a difficulty in disassembling or assembling by one worker. For this reason, there is a situation in which improvement is required, such as an additional input of one worker.

On the other hand, in the prior art literature, domestic registered utility model No. 20-0443895 discloses a technique for increasing the existing wear resistance and extending the service life through the use of a ceramic material, but this As a technology that combines stainless material and ceramic material, it is still expensive to manufacture, heavy, and difficult to handle by workers, so there are problems with poor practicality, such as not many places to install. There was a problem that the impact was transmitted to the ceramic material and there was a high risk of damage.

Republic of Korea Registered Utility Model Publication No. 20-0443895

The present invention has been devised to solve the above-mentioned problems of the prior art and was devised in consideration of this, and the component parts are made of ceramic material and the resin outer surface is coated on the outer surface by an insert injection method to ensure durability for the part in contact with the limestone slurry while ensuring the overall weight Provides a classifier cyclone for desulfurization facilities in thermal power generation systems and a manufacturing method thereof, which enables the pursuit of weight reduction by reducing but it has a purpose.

The present invention is manufactured using an insert injection method, but ceramic and resin are positioned inside and outside, each component is provided in a form that is closely coupled to each other, and the thermal power generation system is desulfurized to enable use or easy disassembly by fastening and assembling them. An object of the present invention is to provide a classifier cyclone for equipment and a method for manufacturing the same.

Classifier cyclone for desulfurization equipment of thermal power generation system according to the present invention for achieving the above object is a body having a through-hollow, vortex finder 110, inlet head 120, cone 130, nozzle In the classifier cyclone 100 for desulfurization equipment of thermal power generation system, which is composed of 140 but is composed of a finished product by fastening and assembling these component parts, and is used to remove sulfur using limestone slurry, the vortex finder Reference numeral 110 denotes a double structure including a ceramic inner covering 111 made of a ceramic material and a resin outer covering 112 formed integrally by being closely coupled to the outer surface of the ceramic inner covering 111; The inlet head 120 is a body having an inlet pipe portion (IP) and includes a ceramic inner covering material 121 made of a ceramic material, and a resin outer covering material 122 formed integrally by being closely coupled to the outer surface of the ceramic inner covering material 121 . is a double structure having; The cone 130 is a cone-shaped body having a structure that tapers in the downward direction at the bottom, and the ceramic inner sheath 131 made of a ceramic material, and the resin outer sheath which is integrally formed by being closely coupled to the outer surface of the ceramic inner covering material 131 . double structure with ash 132; The nozzle 140 has a double structure including a ceramic inner covering material 141 made of a ceramic material, and a resin outer covering material 142 formed integrally by being closely coupled to the outer surface of the ceramic inner covering material 141; The vortex finder 110 , the inlet head 120 , the cone 130 , and the nozzle 140 are each formed with a flange portion F at positions corresponding to each other so as to be coupled and assembled with each other; The ceramic inner material 111, 121, 131, 141 and the corresponding resin outer material 112, 122, 132, 142 are integrally coupled into one body by an insert injection method. do.

Here, the ceramic inner coverings 111, 121, 131, and 141 are non-metallic inorganic materials or silicon carbide (SiC) containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide, and the resin shell The ash 112, 122, 132, and 142 may be made of at least one selected from polyurethane, silicone, ethylene propylene rubber, butyl rubber, and EVA resin.

Here, each of the ceramic linings 111, 121, 131, and 141 is impregnated with oil to form a lubricating layer on the inner surface, or a lubricating layer is formed by filling the inner surface with a solid lubricant to form a lubricating layer with lime slurry. It can be configured to exhibit low friction characteristics due to the lubricating effect upon contact.

In addition, the method for manufacturing a classifier cyclone for a desulfurization facility of a thermal power generation system according to the present invention for achieving the above object is a body having a through-hollow, and consists of a vortex finder, an inlet head, a cone, and a nozzle. In the method for manufacturing a classifier cyclone for a desulfurization facility of a thermal power generation system, which is composed of a finished product by fastening and assembling between parts, and is used to remove sulfur using limestone slurry, (A) all have a body having a through-hollow, vortex forming and manufacturing components including a finder, an inlet head, a cone, and a nozzle from a ceramic material; (B) inserting each component including the vortex finder, inlet head, cone and nozzle made of the ceramic material individually into a mold; (C) integrally forming a resin shell on the outer surface of each component by injecting a molten resin material in a state in which each component including the vortex finder, inlet head, cone, and nozzle made of the ceramic material is inserted into the mold ; (D) drying after step (C); (E) making a classifier cyclone into a finished product by fastening and assembling the components of the ceramic material vortex finder, inlet head, cone, and nozzle, which have undergone the step (D) above; characterized by including.

Here, the ceramic material is a non-metallic inorganic material or silicon carbide (SiC) containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide, and the molten resin material is polyurethane, silicon, ethylene propylene rubber, butyl rubber , it may be at least one selected from among EVA resins.

Here, in step (C), insert injection is performed in a natural pressure state under the action of gravity and a temperature of 140 to 220 ° C. The resin outer material is coated on the ceramic inner material for each component, and in the (D) step, It can be dried for 10-15 hours.

Here, in step (A), each component including the vortex finder, inlet head, cone, and nozzle made of a ceramic material is impregnated with oil to form a lubricating layer on the inner surface or fill the inner surface with a solid lubricant By forming a lubricating layer, it can be manufactured to exhibit low friction characteristics due to the lubricating effect when in contact with lime slurry.

Here, the oil is a polyalphaolefin having a kinematic viscosity (at 40° C.) of 50 cSt to 400 cSt; The solid lubricant may be a mixture of molybdenum sulfide and graphite.

Here, in step (A), for each component including the vortex finder, inlet head, cone, and nozzle made of a ceramic material, a non-metallic inorganic material containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide Alternatively, by adding molybdenum sulfide and graphite to silicon carbide (SiC) and manufacturing it, it may be provided to exhibit low friction characteristics due to a lubricating effect upon contact with lime slurry.

Here, in step (A), for each component including the vortex finder, inlet head, cone, and nozzle made of a ceramic material, a non-metallic inorganic material containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide Alternatively, after molding and manufacturing with silicon carbide (SiC), a coating layer is formed on the inner surface with a mixture of molybdenum sulfide and graphite added to oil to exhibit low friction properties due to a lubricating effect upon contact with lime slurry.

According to the present invention, a thermal power generation system desulfurization facility in which ceramic and resin are located inside and outside each component and are provided in a form in which they are closely coupled to each other, and these components are fastened and assembled to enable use or easy separation and disassembly. A classifier cyclone can be provided for desulfurization, and it is possible to achieve light weight by reducing the overall weight while securing abrasion resistance and durability for the part in contact with limestone slurry during desulfurization. It is possible to provide advantages of preventing easy bursting and frequent replacement, while improving ease of use, such as facilitating operation.

1 is an assembly diagram showing a classifier cyclone for a desulfurization facility of a thermal power generation system according to an embodiment of the present invention.
2 is an exploded configuration diagram showing a classifier cyclone for a desulfurization facility of a thermal power generation system according to an embodiment of the present invention.
3 is a schematic cross-sectional view illustrating a structure of a lubricating layer on the ceramic inner skin side in a classifier cyclone for a desulfurization facility of a thermal power generation system according to an embodiment of the present invention.
4 is a schematic process flow chart showing a method for manufacturing a classifier cyclone for a desulfurization facility of a thermal power generation system according to an embodiment of the present invention.
5 is a process diagram showing essential parts for explaining a method for manufacturing a classifier cyclone for a desulfurization facility of a thermal power generation system according to an embodiment of the present invention.

Preferred embodiments of the present invention will be described with reference to the accompanying drawings, and the purpose and configuration of the present invention and its features will be better understood through such detailed description.

Classifier cyclone 100 for desulfurization equipment of thermal power generation system according to an embodiment of the present invention, as shown in FIGS. 1 to 3, all have a through-hollow body, vortex finder 110, inlet head 120 ), a cone 130 , and a configuration including a nozzle 140 .

The vortex finder 110 , the inlet head 120 , the cone 130 , and the nozzle 140 are sequentially fastened and assembled from the upper side to the lower side using a fastening member such as a clamp to form a finished product.

The classifier cyclone 100 for the desulfurization facility of the thermal power generation system having the above configuration is used to remove sulfur using the limestone slurry.

The vortex finder 110 has a dual structure including a ceramic inner sheath 111 made of a ceramic material and a resin outer sheath 112 that is integrally formed by being closely coupled to the outer surface of the ceramic inner covering material 111 .

The vortex finder 110 is formed so that the lower portion is inserted into the inlet head 120 .

The inlet head 120 is a body communicating with an internal through-hollow on one side and having an inlet pipe for inputting limestone slurry for desulfurization, a ceramic lining 121 made of a ceramic material, and a ceramic lining 121 ) is provided in a double structure having a resin shell material 122 integrally formed by being closely coupled to the outer surface.

The cone 130 is a cone-shaped body having a structure that tapers in the downward direction at the bottom, and is formed integrally with a ceramic inner covering material 131 made of a ceramic material, and a resin that is closely coupled to the outer surface of the ceramic inner sheath material 131 . It is provided in a double structure having an outer covering material (132).

The nozzle 140 is provided in a double structure including a ceramic inner covering material 141 made of a ceramic material, and a resin outer covering material 142 formed integrally by being closely coupled to the outer surface of the ceramic inner covering material 141 .

The nozzle 140 is formed so that the upper portion is inserted into the cone 130 .

Each of the vortex finder 110 , the inlet head 120 , the cone 130 , and the nozzle 140 is formed with a flange portion at a position corresponding to each other so as to be coupled and assembled with each other.

Between the ceramic inner coverings 111, 121, 131, and 141 of the components and the corresponding resin coverings 112, 122, 132, and 142, the insert injection method is used to form a single body. are united together

Here, the ceramic linings 111, 121, 131, and 141 are non-metallic inorganic materials or silicon carbide (SiC) containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide for durability and weight reduction. can be made with

Here, the resin shell material 112, 122, 132, 142 may be made of at least one selected from polyurethane, silicone, ethylene propylene rubber, butyl rubber, and EVA resin to exhibit a cushioning function by elasticity. have.

In addition, in the constituent parts of the vortex finder 110, the inlet head 120, the cone 130, and the nozzle 140, the ceramic linings 111, 121, 131, and 141 each have , it is possible to have a configuration in which the lubricating layer 150 is formed on the inner surface by impregnating or coating with oil in a state where ceramic molding is completed. can be configured to do so.

In some cases, it is possible to have a configuration in which the lubricating layer 150 is formed by filling the inner surface with a solid lubricant after ceramic molding is completed, and through this, it is also configured to exhibit low friction characteristics due to the lubricating effect when in contact with the lime slurry. can do.

Here, the solid lubricant may be configured in the form of forming grooves on the inner surfaces of the ceramic inner surfaces 111, 121, 131, and 141 and then filling the inner grooves, and through sintering, the ceramic inner material and the ceramic inner material are formed. It can be configured in a form to increase the adhesion and durability of the

Sometimes, when the components of the vortex finder 110, the inlet head 120, the cone 130, and the nozzle 140 are formed of a ceramic material, oil or a solid lubricant can be added to the ceramic material. .

Here, as the oil, polyalphaolefin may be used, and it is preferable to use one having a kinematic viscosity (at 40° C.) of 50 cSt to 400 cSt.

The solid lubricant may be a mixture of molybdenum sulfide and graphite.

On the other hand, below will be described a manufacturing method of the classifier cyclone 100 for the desulfurization facility of the thermal power generation system according to the present invention having the above-described configuration.

That is, as already described above, all of the body has a through-hole, and is composed of a vortex finder 110 , an inlet head 120 , a cone 130 , and a nozzle 140 , but by fastening and assembling these components to form a finished product. It is a manufacturing method for manufacturing a classifier cyclone 100 for a desulfurization facility of a thermal power generation system used to remove sulfur using limestone slurry.

1 to 5 for the manufacturing method of the classifier cyclone 100 for the desulfurization facility of the thermal power generation system according to the present invention, a ceramic forming step (S10), a mold inserting step (S20), a molten resin injection step (S30) ), a drying step (S40), and an assembling step (S50).

The ceramic forming step (S10) is a body having a through-hole, and the components including the vortex finder 110, the inlet head 120, the cone 130, and the nozzle 140 are molded and manufactured with a ceramic material. This is the stage of preparation.

That is, it is a step of completing the shape of each of the components of the vortex finder 110 , the inlet head 120 , the cone 130 , and the nozzle 140 through a molding and sintering process using a ceramic material.

In other words, it is a step of providing the ceramic inner coverings 111, 121, 131, and 141 having a predetermined shape and a shape that can be assembled with each other.

Here, the ceramic material may be a non-metallic inorganic material or silicon carbide (SiC) containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide for durability and weight reduction.

The mold insert step (S20) is inserted into the mold for each of the components of the vortex finder 110, the inlet head 120, the cone 130, and the nozzle 140 provided through the ceramic forming step (S10). It is a step of placing and processing inserts.

In the molten resin injection step (S30), the molten resin material is injected in a state in which each ceramic product (which is a ceramic lining) is inserted into the mold through the mold inserting step (S20). This is the step of forming one.

Here, each component is a ceramic lining having the shape of a vortex finder, an inlet head, a cone, and a nozzle.

Here, the molten resin material may use at least one selected from polyurethane, silicone, ethylene propylene rubber, butyl rubber, and EVA resin so as to exhibit a cushioning function due to elasticity.

Here, in the molten resin injection step (S30), the molten resin is injected into the outer surface of the ceramic lining and insert-injected, but the insert-injection is performed in a natural pressure state where gravity acts and a temperature of 140 to 220°C.

Through this, it is possible to complete the work of coating the resin outer covering material 112, 122, 132, 142 on the ceramic inner covering material 111, 121, 131, and 141 for each component, and this has a double structure. A vortex finder 110 , an inlet head 120 , a cone 130 , and a nozzle 140 having a .

In the drying step ( S40 ), the vortex finder 110 , the inlet head 120 , the cone 130 , and the nozzle 140 having a double structure are separated from each other in the mold and then dried.

Here, the drying step (S40) may be dried for 10 to 15 hours at room temperature (20 to 30 ℃).

The assembling step (S50) is the vortex finder 110, the inlet head 120, the cone 130, the nozzle 140, in which the vertical sheathing material is integrally formed on the outer surface of the ceramic inner covering material after the drying step (S40) is completed. It is a step of making the classifier cyclone 100 into a finished product by fastening and assembling the components between the components with a fastening member such as a clamp.

In addition, in the ceramic forming step (S10), a lubricating layer ( 150), and through this, it can be configured to exhibit low friction characteristics due to the lubricating effect upon contact with the lime slurry.

Sometimes, in a state in which the ceramic lining material is manufactured through ceramic molding, a solid lubricant may be filled on the inner surface to form the lubricating layer 150, and through this also, low friction due to the lubricating effect upon contact with the lime slurry characteristics can be configured.

Here, the solid lubricant may be configured in the form of forming grooves on the inner surfaces of the ceramic inner surfaces 111, 121, 131, and 141 and then filling the inner grooves, and through sintering, the ceramic inner material and the ceramic inner material are formed. It can be configured in a form to increase the adhesion and durability of the

Sometimes, when the components of the vortex finder 110, the inlet head 120, the cone 130, and the nozzle 140 are formed of a ceramic material, oil or a solid lubricant can be added to the ceramic material. .

Here, as the oil, polyalphaolefin may be used, and it is preferable to use one having a kinematic viscosity (at 40° C.) of 50 cSt to 400 cSt.

Here, the solid lubricant may be a mixture of molybdenum sulfide and graphite.

In addition, in the ceramic forming step ( S10 ), for each component including the vortex finder, inlet head, cone, and nozzle made of a ceramic material, aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide are non-metallic minerals By adding molybdenum sulfide and graphite to the material or silicon carbide (SiC) and manufacturing it, it can be provided to exhibit low friction characteristics due to the lubricating effect when in contact with the lime slurry.

In addition, in the ceramic forming step ( S10 ), for each component including the vortex finder, inlet head, cone, and nozzle made of a ceramic material, aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide are non-metallic minerals After molding and manufacturing with material or silicon carbide (SiC), a coating layer is formed on the inner surface with a mixture of molybdenum sulfide and graphite added to oil to exhibit low friction properties due to lubricating effect when in contact with lime slurry. .

Accordingly, through the present invention described above, it is manufactured using the insert injection method, but ceramic and resin are located inside and outside, so that each component is provided in a form that is closely coupled to each other and fastened and assembled to facilitate use or separation and disassembly. It is possible to provide the classifier cyclone for the desulfurization facility of the thermal power generation system that makes it possible, and it is possible to pursue light weight by reducing the overall weight while securing the durability of the part in contact with the limestone slurry during the desulfurization operation. It is possible to improve convenience of use, such as facilitating assembly or disassembly by a human operator, while providing advantages of preventing easy bursting and frequent replacement.

The embodiments described above are merely illustrative of preferred embodiments of the present invention and are not limited to these embodiments, and various modifications and variations or modifications by those skilled in the art within the technical spirit and claims of the present invention It will be said that the substitution of steps can be made, and it will be said that it falls within the technical scope of the present invention.

100: classifier cyclone
110: vortex finder
120: inlet head
130: cone
140: nozzle
111,121,131,141: ceramic lining material
112,122,132,142: resin outer material

Claims (10)

All of them have a through-hollow body, and are composed of a vortex finder 110, an inlet head 120, a cone 130, and a nozzle 140, but by fastening and assembling these components to form a finished product, using limestone slurry In the classifier cyclone 100 for the desulfurization facility of the thermal power generation system used to remove sulfur,
The vortex finder 110 has a double structure including a ceramic inner covering material 111 made of a ceramic material and a resin outer covering material 112 formed integrally with the outer surface of the ceramic inner covering material 111;
The inlet head 120 is a body having an inlet pipe portion (IP) and includes a ceramic inner covering material 121 made of a ceramic material, and a resin outer covering material 122 formed integrally by being closely coupled to the outer surface of the ceramic inner covering material 121 . is a double structure having;
The cone 130 is a cone-shaped body having a structure that tapers in the downward direction at the bottom, and the ceramic inner sheath 131 made of a ceramic material, and the resin outer sheath which is integrally formed by being closely coupled to the outer surface of the ceramic inner covering material 131 . double structure with ash 132;
The nozzle 140 has a double structure including a ceramic inner covering material 141 made of a ceramic material, and a resin outer covering material 142 formed integrally by being closely coupled to the outer surface of the ceramic inner covering material 141;
The vortex finder 110 , the inlet head 120 , the cone 130 , and the nozzle 140 are each formed with a flange portion F at positions corresponding to each other so as to be coupled and assembled with each other;
The ceramic inner coverings 111, 121, 131 and 141 and the corresponding resin outer coverings 112, 122, 132, and 142 are integrally coupled into one body by an insert injection method;
Each of the ceramic linings 111, 121, 131, and 141 is impregnated with oil to form an oil layer on the inner surface, or a lubricating layer is formed by filling the inner surface with a solid lubricant to lubricate when in contact with lime slurry. Classifier cyclone for desulfurization facilities of thermal power generation system, characterized in that it is configured to exhibit low friction characteristics due to the effect. The method of claim 1,
The ceramic linings 111, 121, 131, and 141 are non-metallic inorganic materials or silicon carbide (SiC) containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide,
The resin shell material 112, 122, 132, 142 is a classifier for a desulfurization facility of a thermal power generation system, characterized in that at least one selected from polyurethane, silicone, ethylene propylene rubber, butyl rubber, and EVA resin. cyclone. delete All of them have a hollow body, consisting of a vortex finder, inlet head, cone, and nozzle, and are composed of a finished product by fastening and assembling these components. Desulfurization facility of thermal power generation system used to remove sulfur using limestone slurry In the method for manufacturing a classifier cyclone for
(A) all of the body having a through-hole, comprising the steps of forming and manufacturing components including a vortex finder, an inlet head, a cone, and a nozzle from a ceramic material;
(B) inserting each component including the vortex finder, inlet head, cone, and nozzle made of the ceramic material individually into a mold;
(C) integrally forming a resin shell on the outer surface of each component by injecting a molten resin material in a state in which each component including the vortex finder, inlet head, cone, and nozzle made of the ceramic material is inserted into the mold ;
(D) drying after step (C);
(E) making a classifier cyclone into a finished product by assembling components of a ceramic material including a vortex finder, an inlet head, a cone, and a nozzle, which have undergone the step (D); Classifier cyclone manufacturing method for desulfurization equipment of thermal power generation system, characterized in that it comprises a. 5. The method of claim 4,
The ceramic material is a non-metallic inorganic material or silicon carbide (SiC) containing aluminum oxide as a main component and silicon oxide, calcium oxide and iron oxide,
The molten resin material is at least one selected from polyurethane, silicone, ethylene propylene rubber, butyl rubber, and EVA resin. 5. The method of claim 4,
In the step (C), insert injection is performed in a natural pressure state where gravity acts and a temperature of 140 to 220 ° C.
In step (D), a method for manufacturing a classifier cyclone for a desulfurization facility of a thermal power generation system, characterized in that drying is performed for 10 to 15 hours. 5. The method of claim 4,
In step (A), for each component including a vortex finder, inlet head, cone, and nozzle made of a ceramic material, the lubricating layer is formed on the inner surface by impregnating it with oil or filling the inner surface with a solid lubricant to form a lubricating layer A method for manufacturing a classifier cyclone for a desulfurization facility in a thermal power generation system, characterized in that it is manufactured to exhibit low friction characteristics due to a lubricating effect upon contact with lime slurry by forming a. 8. The method of claim 7,
the oil is a polyalphaolefin having a kinematic viscosity (at 40° C.) of 50 cSt to 400 cSt;
The solid lubricant is a method for manufacturing a classifier cyclone for a desulfurization facility of a thermal power generation system, characterized in that it is a mixture of molybdenum sulfide and graphite. 5. The method of claim 4,
In step (A), for each component including a vortex finder, inlet head, cone, and nozzle made of a ceramic material,
By molding and manufacturing aluminum oxide as a main component and adding molybdenum sulfide and graphite to silicon carbide (SiC) or a non-metallic inorganic material containing silicon oxide, calcium oxide, and iron oxide, low friction properties due to the lubricating effect upon contact with lime slurry A method for manufacturing a classifier cyclone for desulfurization equipment of a thermal power generation system, characterized in that it is provided so as to exert the effect. 5. The method of claim 4,
In step (A), for each component including a vortex finder, inlet head, cone, and nozzle made of a ceramic material,
After molding and manufacturing with aluminum oxide as a main component and silicon carbide (SiC) or a non-metallic inorganic material containing silicon oxide, calcium oxide and iron oxide, a coating layer is formed on the inner surface with a mixture of molybdenum sulfide and graphite added to oil to form a lime slurry. A method for manufacturing a classifier cyclone for desulfurization equipment of a thermal power generation system, characterized in that it is provided to exhibit low friction characteristics due to a lubricating effect when in contact with the .

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