KR101512250B1 - Method and device for preventing deposition of ash in heating furnace - Google Patents

Abstract

It is an object of the present invention to provide a method for predicting the adhesion of a metal-based compound or a metal-containing compound in a heating furnace using a mixture added to various types of solid fuels including hot-nitrogen as fuel, Is prevented from being attached. The method for suppressing the adhesion of a heating furnace according to the present invention includes a step (S1) of measuring a composition of a sintering component of a plurality of kinds of solid fuels to be used in a heating furnace and an inorganic composition of a metal compound or a metal- Containing compound is added in a plurality of mixing ratios and the composition of the ash component of the solid fuel mixed with a plurality of mixing ratios and the predetermined atmosphere temperature and the atmospheric gas composition And a step (S2) of determining a predetermined blending ratio at which a composition of the ash component in which the slag ratio becomes equal to or less than the reference value is obtained, based on the slag ratio indicating the ratio of the slag to the slag. Further, the present invention includes a step (S3) of supplying a mixture in which a metal compound or a metal-containing compound is added and mixed at a predetermined mixing ratio to the heating furnace as fuel.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heating furnace,

TECHNICAL FIELD The present invention relates to a method of suppressing ash adhesion of a heating furnace using a solid fuel to which a metal-based compound or a metal-containing compound is added as fuel, and a turn adhesion suppression device.

BACKGROUND ART [0002] In a heating furnace (generally referred to as a furnace for burning solid fuel) such as a boiler using a single kind or a plurality of kinds of solid fuels including hot-nitrogen, the solid fuel pulverized in the pulverizer is mixed with air As a fuel. The heating furnace includes a furnace for generating heat by burning the supplied fuel in a burner or the like and a heat transfer tube group disposed downstream from the furnace for flowing the combustion gas to heat exchange therewith, The combustion gas is discharged from the chimney. Here, the heat transfer pipe group includes an upper heat transfer unit having a secondary heater, a tertiary heater, a final heater, and a secondary heat exchanger disposed in parallel above the furnace at predetermined intervals, and a primary heater , A primary reheater, and a rear portion heat transfer portion including a separator (economizer).

In such a heating furnace, since the furnace is generated from the burned coal, it flows by the combustion gas of the furnace, and is attached to the wall surface of the furnace or the heat transfer tube group arranged from the upper side to the lower side of the furnace, Or fouling occurs. When slagging or fouling occurs due to deposition on the wall of the furnace or the heat transfer pipe group, the heat transfer surface of the heat transfer pipe is blocked, and the heat absorption efficiency is significantly lowered. Further, when a large clinker is generated on the wall surface by slagging or fouling, there arises a problem that the clinker falls and the furnace pressure greatly fluctuates, the heat transfer pipe of the furnace floor is damaged, and the furnace bottom is occluded. Further, since the upper heat transfer portions provided above the furnace are disposed at narrow intervals, when the heat exchanger is attached, the furnace pressure greatly fluctuates and the gaps between the heat transfer tubes increase to close the gas flow path, There is a risk of causing a driving disorder. Further, in the vicinity of the burner, since the temperature near the wall surface of the furnace is raised by radiant heat of the combustion flame of the fuel, it is easy to melt and melt in the group of relatively low temperature heat transfer tubes, and there arises a problem that a large clinker tends to grow.

Therefore, in order to stably operate the heating furnace, it is necessary to predict in advance the possibility that the burning of the solid fuel is caused by the burning of the solid fuel, thereby avoiding the problem of the burning. Therefore, it is attempted to indicate the possibility of meeting attachment as an indicator.

For example, in Non-Patent Document 1, there is proposed a method of predicting the possibility of adhesion of the sludge, based on an index and evaluation criteria based on sashimi showing the sludge containing element as an oxide. However, the indicators and evaluation criteria disclosed in the non-patent document 1 are aimed at bituminous coal which is a high-quality coal with little problems such as meeting and the like. Recently, demand for hot crude (for example, bituminous coal, lignite, , High calcium carbonate, etc.). Therefore, there is a problem that the relationship between the index and the slip adhesion disclosed in the non-patent document 1 does not necessarily coincide with each other.

Therefore, a technique for predicting adhesion of a meeting by measuring sintering degree of sintering meeting by sintering coal fly ash obtained by carbonizing the coal to be used in advance, as disclosed in Patent Document 1, has been developed. However, the sinterability and meltability of the sintered body are largely influenced not only by the temperature but also by the atmospheric gas composition. If the atmosphere is CO or H ₂ Or the like, the lowering of the softening point and the melting point are lowered, and the sintering easily becomes possible. Further, if the atmosphere is an oxidizing atmosphere, the softening point and the melting point increase, and sintering becomes difficult. Therefore, in the technique of Patent Document 1 in which the atmospheric gas composition is not taken into consideration, there is a problem that it is difficult to predict the turn adhesion in the heating furnace with high accuracy.

Further, in order to lower the unburned matter, there has been developed a technique of adding a metal oxide such as calcium, magnesium, iron or copper to coal as in Patent Document 2. However, in Patent Document 2, the content ratio of the unburned components is only calculated, and the relationship between the amount of addition of the metal oxide and the adhesion in the heating furnace is not described. Further, in Patent Document 2, since the addition amount of the metal oxide corresponding to the thermal carbon to be used is not determined, the proper amount of the metal oxide to be added is not fixed, .

Japanese Patent Application Laid-Open No. 2004-361368 Japanese Patent Application Laid-Open No. 2008-169338

Gordon Couch, Understanding slagging and fouling during pf combustion (IEACR / 72), 1994

A problem to be solved by the present invention is to provide a heating furnace in which a mixture of various kinds of solid fuels containing a thermal chemical is added as a fuel to which a metal compound or a metal containing compound is added, The present invention provides a method and a device for suppressing adhesion of a heating furnace in which the adhesion of the substrates in the heating furnace can be predicted with high accuracy and the adhesion of the substrates can be suppressed.

The method for suppressing adhesion of a heating furnace according to the present invention is a method for suppressing the adhesion of a plurality of kinds of solid fuels and a method of suppressing the addition of an inorganic component of a metal- A step of previously measuring the composition of the metal-based compound or the metal-containing compound in a mixture ratio of the metal-based compound or the metal-containing compound at a plurality of mixing ratios, Based on a predetermined atmospheric temperature and a slag ratio representing a ratio of the slag in the atmospheric gas composition to a predetermined amount of the ash component calculated in advance for the plurality of kinds of solid fuels added in the ratio A predetermined mixture in which the composition of the ash component in which the slag ratio becomes the reference value or less is obtained Based compound or a metal-containing compound obtained by mixing the plural kinds of solid fuels with the metal-based compound or the metal-containing compound at the predetermined mixing ratio and mixing the plurality of kinds of solid fuels with the metal- And supplying the mixture to the heating furnace as fuel.

Further, the apparatus for suppressing the adhesion of the heating furnace according to the present invention is a device for suppressing the adhesion of a plurality of kinds of solid fuels, and a composition of each of the plural kinds of solid fuels, Wherein the composition of the components of the plurality of types of solid fuels mixed and added with the metal compound or the metal containing compound at a plurality of mixing ratios and a composition of the metal compound or the metal containing compound Based on the predetermined atmospheric temperature and the slag ratio representing the ratio of the slag in the atmospheric gas composition to the predetermined amount of the ash component calculated in advance for the plural kinds of solid fuels added and mixed at the mixing ratio of Wherein the composition of the slag component in which the slag ratio in the slag is less than or equal to a reference value And a fuel supply amount adjustment unit for adjusting the supply amounts of the plural kinds of solid fuels and the metal compound or the metal containing compound based on the predetermined mixing ratio determined by the calculation unit .

The present invention is focused on slag, which is a component that is melted by combustion in a heating furnace, floats on the air stream of combustion air in the heating furnace, and is attached to the furnace wall or heat transfer pipe group. In the present invention, the slag ratio calculated for a plurality of types of solid fuels, in which a metal compound or a metal-containing compound is added and mixed as a mixture at a plurality of mixing ratios, the composition of the ash components of a plurality of kinds of solid fuels, Or the composition of the inorganic component of the metal-containing compound is determined so that the composition of the ash component in which the slag ratio becomes equal to or less than the reference value is determined from a plurality of mixing ratios. Therefore, on the basis of the slag ratio, which is an evaluation index newly constructed in the present invention, a proper blending ratio is determined from a plurality of blending ratios such that the slag ratio becomes the composition of the ash component whose blinding property is evaluated in advance below the reference value , It is possible to estimate the turn adhesion in the heating furnace with high accuracy and to suppress the adhesion of the meeting.

Here, the term "solid fuel" includes coal, sludge, biomass fuel, and the like. Further, since the amount of heat is important in the heating furnace, the supply amount of the solid fuel to be the fuel is determined so that the amount of heat supplied to the heating furnace becomes constant. Here, the metal-based compounds or metal-containing compound is a compound of magnesium or aluminum as the main component of the metal element, of magnesium or a metal oxide containing aluminum, metal hydroxide, metal carbonate, etc. [for example, MgO, Mg (CO ₃ ), Mg (OH) ₂ , Al ₂ O ₃ , Al (OH) ₃ and the like], magnesium oxides, aluminum salts, organic salts and minerals. Specific examples of the metal-based compound or metal-containing compound include inorganic salts such as magnesium oxide MgO (goto), magnesium peroxide MgO ₂ , magnesium hydroxide Mg (OH) ₂ , magnesium carbonate MgCO ₃ (oxalic acid) magnesium CaMg (CO _{3) 2} (high dilution, dolomite), magnesium nitrate Mg (NO _{3) 2,} magnesium sulfate MgSO _4, sulfurous acid magnesium MgSO _3, phosphate 3 magnesium Mg ₃ (PO _{4) 2} and 8H ₂ O, potassium permanganate, magnesium and Mg (MnO _{4) 2,} mineral 3 magnesium silicate 2MgO and 3SiO ₂ and nH ₂ O, spinel (spinel) MgO and Al ₂ O _3, golseok _{Mg 3 Si 4 O 10 (OH} ) 2, serpentinite Mg ₃ Si ₂ O ₅ (OH) ₄ and organic salts of magnesium acetate Mg (CH ₃ COO) _2, magnesium citrate, magnesium L- glutamic acid, benzoic acid, magnesium C ₁₄ H ₁₀ MgO _4, magnesium stearate, _{Mg (CH 3 (CH 2)} 16 COO) ₂ . The term "metal oxide" means a metal oxide having an oxidizing power for oxidizing carbon in the solid fuel under an environment in a heating furnace, and includes a raw material of a metal oxide. The term " raw material of metal oxide " means a compound that generates a metal oxide by thermal decomposition.

Further, the method for suppressing the adhesion of the heating furnace according to the present invention is a method for suppressing the adhesion of a plurality of kinds of solid fuels, A step of previously measuring the composition of the components of the solid fuel, a step of preliminarily measuring the composition of the components of the plural types of solid fuels mixed with a plurality of kinds of metal-based compounds or metal- A method for producing a slag in a predetermined atmospheric temperature and atmospheric gas composition among predetermined components of a predetermined amount of an ash component calculated in advance for a plurality of kinds of solid fuels to which the above-mentioned metal-based compound having an average particle diameter or a metal- Of the slag in the furnace, The method comprising the steps of: determining a predetermined mixing ratio and a predetermined average particle diameter at which a composition of the ash component in which the ratio becomes less than or equal to a reference value is determined; and a step of mixing the plurality of kinds of solid fuel and the metal- And a step of supplying, as fuel, the mixture of the plural kinds of solid fuels obtained by adding and mixing at the predetermined mixing ratios and the metal compound or the metal containing compound to the heating furnace.

Further, the apparatus for suppressing the adhesion of the heating furnace according to the present invention is a device for suppressing the adhesion of a plurality of kinds of solid fuels, and a composition of each of the plural kinds of solid fuels, The composition of the components of the plural types of solid fuels to which a plurality of kinds of metal-based compounds or metal-containing compounds having a mean particle diameter are added and mixed at a plurality of mixing ratios, Of the average particle diameter of the metal compound or the metal-containing compound at a mixing ratio of a plurality of kinds and mixing the slag Based on the slag ratio, Based on the predetermined mixing ratio and the predetermined average particle diameter determined by the calculating section, a predetermined mixing ratio and a predetermined average particle diameter at which a composition of a pour ingredient whose ratio becomes a reference value or less is obtained, And a fuel supply amount adjusting unit for adjusting the supply amount of the solid fuel and the metal compound or the metal-containing compound.

The present invention is focused on slag, which is a component that is melted by combustion in a heating furnace, floats on the air stream of combustion air in the heating furnace, and is attached to the furnace wall or heat transfer pipe group. In the present invention, the slag ratio calculated for a plurality of kinds of solid fuels in which a plurality of kinds of metal-based compounds having an average particle diameter or metal-containing compounds are mixed as additives at a plurality of mixing ratios, A predetermined mixing ratio is determined from a plurality of mixing ratios and a predetermined average particle diameter is determined from a plurality of average particle diameters based on the composition of the metal compound or the composition of the inorganic component of the metal compound. Therefore, in the present invention, the slip ratio is determined based on the slag ratio, which is newly established in the present invention, and a predetermined mixing ratio is determined from a plurality of mixing ratios so that the composition of the slag component becomes the reference value or less At the same time, by determining a predetermined average particle diameter from a plurality of average particle diameters, it is possible to predict the adhesion of the turn in the heating furnace with high accuracy, determine an appropriate mixing ratio, and suppress adhesion of the meeting.

Here, in the method for restraining turnover of the heating furnace and the apparatus for restraining turnover of the furnace according to the present invention, the main component of the metal element of the metal compound or the metal-containing compound is preferably magnesium or aluminum.

On the basis of the results of the comparison of the content of magnesium and aluminum in the slag with the ratio of the slag added to the previously sintered, plural kinds of solid fuels added as additives, the slag ratio decreases as the content of magnesium or aluminum in the slag increases . Therefore, by adding an additive in which the main component of the metal element of the metal compound or the metal-containing compound is magnesium or aluminum to a plurality of kinds of solid fuels, it is possible to suppress the adhesion of the meeting.

Here, the slag ratio is preferably calculated by thermodynamic equilibrium calculation based on the composition of the ash components of the plural kinds of solid fuels to which the metal compound or the metal-containing compound is added at a plurality of mixing ratios . Alternatively, the slag ratio may be selected from the group consisting of a slag generated by heating at a predetermined atmospheric temperature and an atmospheric gas composition measured in advance for the plural kinds of solid fuels to which the metal compound or the metal-containing compound is added at a plurality of mixing ratios, .

The slag ratio is calculated by calculating the slag ratio by calculation of thermodynamic equilibrium based on the composition of the ash components of the plural types of solid fuels in which the metal compound or the metal containing compound is added and mixed at a plurality of mixing ratios to obtain the slag ratio . The slag ratio is calculated from the slag generated by heating at a predetermined atmospheric temperature and atmospheric gas composition measured in advance for a plurality of kinds of solid fuels mixed with a metal compound or a metal containing compound at a plurality of mixing ratios , It is possible to obtain the slag ratio in accordance with the actual conditions of the heating furnace.

In the method for restraining the adhesion of the heating furnace and the furnace in the heating furnace according to the present invention, it is preferable that the reference value is determined so as to lower the slag adhesion rate based on the slag adhesion ratio with respect to the slag ratio . It is preferable that the slip adhesion ratio is calculated as a ratio of the actual slip amount to the slip amount to the slip attached probe inserted in the heating furnace irradiated in advance. It is preferable that the collision amount is calculated as the total amount of collision against the projected area of the turn attaching probe obtained from the shape of the furnace of the heating furnace and the supply amount of the solid fuel, the ash content and the content of the ash.

According to this, it is possible to suppress the adhesion of the meeting by determining the reference value of the slag ratio so as to lower the slag adhesion rate based on the comparison result between the slag ratio and the slag ratio previously examined.

In the method of suppressing the adhesion of the heating furnace and the apparatus for restraining adhesion of the heating furnace according to the present invention, it is preferable that the reference value is 50 to 60 wt% so that the adhesion rate is 5 to 7 wt% Or less.

On the basis of the results of comparison between the slag ratio and the slag ratio previously examined, when the slag ratio is in the range of 50 to 60 wt% or less, the slag adhesion rate is lowered (5 to 7 wt% or less) have.

Here, in the method of suppressing the adhesion of the heating furnace according to the present invention, the predetermined atmospheric temperature and the atmospheric gas composition may be atmospheric temperature and atmospheric gas composition near the burner.

It is preferable that the apparatus for inhibiting the adhesion of the heating furnace according to the present invention further comprises a measuring section for measuring the temperature of the combustion chamber and the composition of the atmosphere in the heating furnace, The temperature of the combustion chamber of the heating furnace and the composition of the atmosphere gas are preferable.

According to this, the slag ratio in the slag in each portion inside the heating furnace can be appropriately determined, and an appropriate mixing ratio of a plurality of kinds of solid fuels can be calculated.

Further, in the method for suppressing the adhesion of the heating furnace according to the present invention and the apparatus for restraining the adhesion of the heating furnace, the predetermined atmospheric temperature and the composition of the atmospheric gas are set such that the highest atmospheric temperature in the design of the heating furnace, It is preferable that the atmospheric gas composition having the highest degree of reduction degree in the design of the atmospheric gas composition at the site of the heating furnace or the atmosphere temperature at the site having such atmospheric gas composition.

According to this, an appropriate mixing ratio of a plurality of kinds of solid fuels can be calculated without depending on the state of the heating furnace. The "atmospheric gas composition with the highest reduction degree in design of the furnace" is CO or H ₂ The concentration of the reducing gas is the highest.

Further, in the method of suppressing the adhesion of the heating furnace according to the present invention and the apparatus for restraining the adhesion of the heating furnace, it is preferable that the average particle diameter of the metal compound or the metal-containing compound is smaller than the mean particle diameter of the solid in the solid fuel .

Based compound or metal-containing compound in the case where the amount of the metal-based compound or metal-containing compound to be added is the same as that of the metal-based compound or the metal- The smaller the average particle diameter of the compound, the smaller the adhesion rate. Therefore, when the average particle diameter of the metal-based compound or the metal-containing compound is smaller than the average particle diameter of the solid in the solid fuel, the adhesion to the heating furnace can be effectively suppressed.

In the method of suppressing the adhesion of the heating furnace and the apparatus for restraining the adhesion of the heating furnace according to the present invention, it is preferable that the average particle diameter of the metal compound or the metal-containing compound is 5 m or less.

Based compound or the metal-containing compound is changed, the amount of the metal-based compound or the metal-containing compound to be added is changed, When the average particle diameter of the particles is small, the adhesion rate decreases. Therefore, when the average particle diameter is small and is not more than 5 탆, the effect of suppressing adhesion of turns is increased.

According to the present invention, there is provided a heating furnace comprising a furnace in which a mixture of a metal compound and a metal-containing compound is added to various types of solid fuels containing zeolite, It is possible to suppress the adhesion of the sintered body by predicting the adhesion of the sintered body in the furnace, thereby enabling stable operation of the heating furnace.

Fig. 1 is a step diagram showing the procedure of the rotation attachment restraining method of the heating furnace according to the present embodiment.
Fig. 2 is a schematic view showing the apparatus for restraining rotation of the heating furnace according to the embodiment. Fig.
3 is a diagram showing a specific example of the relationship between the slag ratio and the slip adhesion rate measured in advance.
4 is a graph showing the relationship between the MgO content ratio and the slag ratio in the slurry according to the first embodiment.
5 is a view showing the relationship between the first times of the Al ₂ O ₃ component contained ratio and the ratio of slag in the second embodiment.
6 is a diagram showing the relationship between the slag ratio and the slip adhesion rate according to the first embodiment.
Fig. 7 is a step diagram showing a procedure of a rotation attachment restraining method in a heating furnace according to a modification of the embodiment.
Fig. 8 is a view showing the particle size distribution of the solid fuel according to the third embodiment. Fig.
9 is a view showing the relationship between the slag ratio and the slip adhesion rate according to the third embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, with reference to the drawings, a description will be given of a concrete embodiment for carrying out a method for restraining rotation attachment and detachment of a heating furnace according to the present invention. It should be noted that the following description is merely illustrative and does not limit the application limitations of the rotation attachment preventing method and the rotation attachment preventing device in the heating furnace according to the present invention. In other words, the method of restraining the adhesion of the heater in the heating furnace and the apparatus for restraining rotation of the heating furnace according to the present invention are not limited to the embodiments described below, and various modifications can be made within the scope of the claims.

First, a description will be given of an example of a method for restraining rotation attachment of a heating furnace according to the present embodiment with reference to Fig. Fig. 1 is a step diagram showing the procedure of the rotation attachment restraining method of the heating furnace according to the present embodiment.

In the method of suppressing the adhesion of the heating furnace according to the present embodiment, as shown in Fig. 1, measurement of the coal composition of each solid fuel to be used in the heating furnace, The additive property of the compound is measured (step S1).

Here, as the coal characteristics of the solid fuel, the moisture content, calorific value, ash content, composition of the ash component and the like of the solid fuel are measured. The term "solid fuel" includes coal, sludge, biomass fuel, and the like.

In addition, as the additive property of the metal-based compound or the metal-containing compound, the moisture content, the inorganic content, and the composition of the inorganic component of the metal-based compound or the metal-containing compound are measured. Here, the metal-based compound or the metal-containing compound means a compound in which the main component of the metal element is magnesium or aluminum, and includes metal oxides, metal hydroxides, metal carbonates, etc. containing magnesium or aluminum (for example, MgO, Mg ₃ ), Mg (OH) ₂ , Al ₂ O ₃ , Al (OH) ₃ and the like], oxo acid salts and organic salts and minerals containing magnesium or aluminum. A metal-based compounds or metal-containing compound, specifically, an inorganic salt of magnesium oxide MgO (Goto), peroxide, magnesium MgO _2, magnesium hydroxide Mg (OH) _2, and oxo acid salts of magnesium carbonate MgCO ₃ (neunggo toseok), calcium magnesium carbonate CaMg (CO _{3) 2} (high dilution, dolomite), magnesium nitrate Mg (NO _{3) 2,} magnesium sulfate MgSO _4, sulfurous acid magnesium MgSO _3, phosphate 3 magnesium Mg ₃ (PO _{4) 2} and 8H ₂ O, potassium permanganate, magnesium Mg (MnO ₄ ) ₂ , and minerals such as magnesium trisilicate 2MgO 3SiO ₂ .nH ₂ O, spinel MgO Al ₂ O ₃ , brittle Mg ₃ Si ₄ O ₁₀ (OH) ₂ , serpentine Mg ₃ Si ₂ O ₅ (OH) ₄ and organic salts of magnesium acetate Mg (CH ₃ COO) _2, magnesium citrate, magnesium L- glutamic acid, benzoic acid, magnesium C ₁₄ H ₁₀ MgO _4, magnesium stearate, _{Mg (CH 3 (CH 2)} 16 COO ) _{2. &} Lt; / RTI > The term "metal oxide" means a metal oxide having an oxidizing power for oxidizing carbon in the solid fuel under an environment in a heating furnace, and includes a raw material of a metal oxide. The term " raw material of metal oxide " means a compound that generates a metal oxide by thermal decomposition.

Next, a predetermined mixing ratio, which is the composition of the ash component in which the slag ratio in the heating furnace becomes the reference value or less, is determined (step S2). The predetermined mixing ratio is a ratio of the composition of the ash components of a plurality of kinds of solid fuels and the ratio of slag in a predetermined atmospheric temperature and atmospheric gas composition among a predetermined amount of ash components calculated in advance for a plurality of kinds of solid fuels Slag < / RTI > The composition of the ash component and the slag ratio are previously measured or calculated for a plurality of kinds of solid fuels in which a plurality of kinds of metal-based compounds having an average particle diameter or metal-containing compounds are added and mixed at a plurality of mixing ratios .

Here, " slag ratio " is an evaluation index of slip adhesion property used in the present embodiment, and means a ratio of slag in a certain amount of solid casting, at any temperature and atmospheric conditions. The term " slag " means a component which is melted by combustion, floats on the combustion stream in the heating furnace, and adheres to the furnace wall or heat transfer pipe group. The reference value of the slag ratio is predetermined. First, the slag ratio is calculated in accordance with the mixing ratio of a plurality of kinds of solid fuels and a plurality of metal-based compounds or metal-containing compounds to be mixed and added to a plurality of kinds of solid fuels. That is, the combination of each solid fuel and the metal-based compound or metal-containing compound to be added to each solid fuel is changed and the mixing ratio of the metal-based compound or the metal-containing compound added to each solid fuel is changed, . Further, a plurality of kinds of slag ratios may be calculated while changing the combination of solid fuels to be mixed with a plurality of kinds of solid fuels, and changing the mixing ratios of the respective solid fuels to be mixed. Here, the slag ratio is a value obtained by dividing the amount of the solid fuel beforehand measured in the most thermodynamically stable state under certain conditions (temperature and atmospheric gas composition), that is, when the free energy? G of Gibbs is close to zero Is obtained by calculating the composition or phase in a losing state by thermodynamic equilibrium calculation. The slag ratio is not limited to the above-described form, but may be calculated by heating each solid fuel in advance and measuring the slag ratio at each temperature and atmospheric gas composition. Thereby, the slag ratio in accordance with the actual heating furnace condition can be obtained.

In order to evaluate the slag ratio which is an evaluation index of the slip adhesion characteristic used in the present embodiment, the slip adhesion rate is calculated. Here, the " turn adhesion rate " means the easiness of attaching the meeting with the ratio of the amount of attachment to the turnover probe relative to the turnover amount of the turnover probe inserted into the furnace in the furnace. The adhesion rate is expressed by the following formula. The " amount of collision with the turn attaching probe " is the total amount of collision with the projected area of the turn attaching probe, and is determined by the supply amount of solid fuel, the ash content and the furnace shape of the heating furnace. Based on the relationship between the calculated slag adhesion ratio and the slag ratio, the value (reference value) of the slag ratio in which the slag adhesion rate is reduced (the slag adhesion rate is about 5 to 7 wt% or less) is determined.

[Equation 1]

In addition, the evaluation for calculating the slip adhesion rate is not necessarily performed in the actual heating furnace, and may be performed in a combustion test or in an actual can heating furnace. Then, a plurality of solid fuels (which may be solid fuels to be used or solid fuels that are not to be used) are burned in advance to investigate the rate of adhesion and calculate the slag ratio of the burned solid fuels, Based on the relationship between the slag ratio and the slag ratio, the slag ratio value (reference value) at which the slag adhesion rate is reduced to about 5 to 7 wt% or less is determined.

In the present embodiment, the slag ratio, which is an evaluation index of the slip adhesion characteristic, is evaluated based on the slag adhesion ratio, but the present invention is not limited to this. A combustion test was conducted while varying the ratio of slag contained in the fuel by using a combustion test furnace or an actual can heating furnace so that the mass of clinker (molten slag) of a size that can not be carried out by the conveyor installed in the heating furnace The slag ratio may be set as a reference value. Alternatively, in the same test, the slag ratio when the main steam temperature / main steam pressure deviates from the specified region or fluctuates may be used as the reference value.

The mixing ratio of a plurality of kinds of solid fuels and a plurality of metal-based compounds or metal-containing compounds to be added to and mixed with a plurality of kinds of solid fuels is used as a parameter to calculate the composition And the composition of the ash components of a plurality of kinds of solid fuels obtained by adding a metal compound or a metal-containing compound at a plurality of mixing ratios from the composition of an inorganic component of a metal compound or a metal-containing compound is calculated. Then, by the thermodynamic equilibrium calculation, the slag ratio in the slag is obtained. From a plurality of blending ratios, a predetermined blending ratio at which the slag ratio in the slurry falls below the reference value of the predetermined slag ratio is calculated. Here, the supply amount of the solid fuel to be the fuel is determined so that the amount of heat supplied to the heating furnace becomes constant.

Further, in the thermodynamic equilibrium calculation, the atmospheric temperature and the atmospheric gas composition near the burner in which the adhesion to the furnace wall is remarkably generated are used. The thermodynamic equilibrium calculation may be performed based on the atmospheric temperature and the atmospheric gas composition of the desired portion of the heat transfer tube group or the like which is susceptible to occurrence of adhesion, and is not limited to the atmosphere temperature and the atmospheric gas composition near the burner. As a result, it is possible to appropriately obtain the ratio of the slag in each part in the heating furnace, and it is possible to appropriately determine the slag ratio of the slag in each part in the heating furnace, and to mix a plurality of kinds of solid fuels with the metal- The ratio can be calculated appropriately.

Further, the thermodynamic equilibrium calculation is not limited to the above-described mode, but may be performed using the atmosphere temperature of the highest temperature in the design of the heating furnace and the composition of the atmosphere having such an atmospheric temperature. The atmosphere gas composition having the highest degree of reduction (the highest concentration of reducing gas such as CO or H ₂ is the highest) in the design of the furnace and the atmospheric temperature of the site having such an atmospheric gas composition may be used. Thus, a predetermined mixing ratio of a plurality of kinds of solid fuels and a metal-based compound or a metal-containing compound to be added to and mixed with a plurality of kinds of solid fuels can be determined without depending on the combustion temperature in the furnace of the heating furnace.

Finally, based on a predetermined mixing ratio of the plurality of kinds of solid fuels calculated in step S2 and the metal-based compound or metal-containing compound to be added to and mixed with a plurality of kinds of solid fuels, the solid fuel and the metal- . After the solid fuel and the mixture of the metal compound and the metal-containing compound are pulverized, they are supplied to the heating furnace as fuel (step S3).

Next, a description will be given of an example of the apparatus for restraining rotation of the heating furnace according to the present embodiment with reference to Fig. Fig. 2 is a schematic view showing the apparatus for restraining rotation of the heating furnace according to the embodiment. Fig.

2, the heating furnace 7 includes hoppers 1 and 2, a fuel supply amount adjusting device (fuel supply amount adjusting portion) 3, a mixer 4, a crusher 5, (Computing unit) 6, and a computing unit (computing unit) The apparatus for restraining rotation of the heating furnace according to the present embodiment comprises a fuel supply amount adjustment device 3 and a computing device 9. [

The hoppers 1 and 2 each hold a solid fuel, a metal compound or a metal-containing compound. Here, the term "solid fuel" includes coal, sludge, biomass fuel, and the like. The "metal compound or metal-containing compound" is a compound in which the main component of the metal element is magnesium or aluminum, and is an oxide, hydroxide, carbonate or the like containing magnesium or aluminum (for example, MgO, Mg (CO ₃ ) Mg (OH) ₂ , Al ₂ O ₃ , Al (OH) _3, etc.]. Although two hoppers are provided in Fig. 2, a plurality of hoppers may be provided. The fuel supply amount adjustment device 3 calculates a fuel supply amount based on a predetermined mixing ratio of a plurality of kinds of solid fuels calculated by a computing unit 9 described later and a metal compound or a metal containing compound to be added to and mixed with a plurality of kinds of solid fuels, The amount of solid fuel, metal-based compound or metal-containing compound from the hoppers 1 and 2 is adjusted. The mixer 4 adds the metal compound or metal-containing compound cut in the fuel supply amount adjusting device 3 to the solid fuel cut in the fuel supply amount adjusting device 3 and mixes them. The pulverizer (5) pulverizes a mixture of the solid fuel mixed with the metal compound or the metal-containing compound mixed in the mixer (4) into pulverized coal. The burner 6 burns the pulverized coal taken in together with the air. The heating furnace (7) burns the pulverized coal to recover heat. Although not shown, the heating furnace 7 is provided with a furnace in which the supplied fuel is burned in the burner 6 or the like to generate heat and a furnace which is disposed downstream from the furnace to flow the combustion gas, And the heat transfer pipe group. The combustion gas from the heating furnace is discharged from the chimney. Further, the heat transfer pipe group includes an upper heat transfer portion provided with a secondary heater, a tertiary heater, a final heater, and a secondary heat exchanger disposed in parallel above the furnace at predetermined intervals, and a primary heater , And a rear heat transfer portion having a primary reheater and a carbon burner.

The calculator 9 is a computer for calculating the coal composition (the moisture content, the heating value, the ash content, the composition of the ash composition, etc.) of each solid fuel to be used in the heating furnace, (The moisture content of the metal compound or the metal-containing compound, the content of the inorganic component, and the composition of the inorganic component) of the compound in advance as data (8). The calculator 9 calculates a plurality of kinds of metal-based compounds or metal-containing compounds by using a mixture ratio of a plurality of types of solid fuels and a plurality of metal-based compounds or metal-containing compounds to be mixed and added to a plurality of kinds of solid fuels as parameters The composition of the ash components of the plurality of kinds of solid fuels mixed in is calculated from the composition of the ash component of the plurality of solid fuels measured in advance and the composition of the inorganic component of the metal compound or the metal containing compound. Then, the arithmetic unit 9 obtains the slag ratio in the rotor by the thermodynamic equilibrium calculation. Next, the operator 9 calculates a predetermined blending ratio from a plurality of blending ratios so that the slag ratio in the blending becomes the determined reference value or less. Here, the supply amount of the solid fuel to be the fuel is determined such that the amount of heat input to the heating furnace becomes constant. The " slag ratio " is an evaluation index of the slip adhesion property used in the present embodiment, and means a ratio of the slag in a certain amount of the solid phase, at any temperature and atmospheric conditions. Since the relationship between the slip ratio and the slag ratio is as described above, the description thereof will be omitted. Further, the reference value of the slag ratio is determined as described in the above-described method of preventing adhesion of the heating furnace according to the present embodiment, and thus the description thereof will be omitted.

In the thermodynamic equilibrium calculation, for example, the atmospheric temperature and the atmospheric gas composition in the vicinity of the burner in which the adhesion to the furnace wall remarkably occurs are used. The atmosphere temperature in the vicinity of the burner and the composition of the atmosphere gas are measured using a measuring device (measuring portion) not shown provided near the burner. Further, the measuring apparatus is not limited to the vicinity of the burner, but may be provided at a desired portion of the heat transfer pipe group or the like which is likely to be attached with a meeting, and the thermodynamic equilibrium calculation may be performed based on the atmospheric temperature and the atmospheric gas composition. As a result, it is possible to appropriately obtain the ratio of the slag in each portion in the heating furnace, and it is possible to appropriately determine the mixing ratio of the metal-based compound or the metal-containing compound to be added and mixed with the plural kinds of solid fuels and plural kinds of solid fuels Can be appropriately calculated. The calculation of the thermodynamic equilibrium is not limited to the above-described mode. The calculation of the thermodynamic equilibrium may be performed using the highest atmospheric temperature in the design of the furnace and the composition of the atmospheric gas at the site having such atmospheric temperature. For example, The atmosphere gas composition having the highest concentration (the concentration of the reducing gas such as CO or H ₂ being the highest) and the atmosphere temperature of the site having such an atmospheric gas composition may be used. Thus, a predetermined mixing ratio of a plurality of kinds of solid fuels and a metal-based compound or a metal-containing compound to be added to and mixed with a plurality of kinds of solid fuels can be determined without depending on the combustion temperature in the furnace of the heating furnace.

The predetermined mixing ratios of the plural kinds of solid fuels and the metal compounds or metal-containing compounds to be added to and mixed with the plural kinds of solid fuels are not limited to those calculated on the basis of the slag ratio obtained in the thermodynamic equilibrium calculation, A form calculated based on the slag ratio in each temperature and atmospheric gas composition measured by heating each solid fuel cycle in advance may be used. Thereby, the slag ratio in accordance with the actual heating furnace condition can be obtained.

As described above, in the heating furnace according to the present embodiment, the slip adhesion suppressing method and the slip adhesion suppressing device are constituted such that they are melted by the combustion in the heating furnace, floated on the air stream of the combustion air in the heating furnace, We are focusing on slag as an ingredient. The slag ratio calculated for a plurality of kinds of solid fuels in which a metal compound or a metal containing compound is added as an additive at a plurality of mixing ratios, A predetermined mixing ratio is determined from a plurality of mixing ratios based on the composition of the ash components of the plural kinds of solid fuels and the composition of the inorganic component of the metal compound or the metal containing compound. Therefore, by evaluating the slip adhesion characteristics based on the slag ratio newly established in the present invention and determining an appropriate mixing ratio from a plurality of kinds of mixing ratios so that the composition of the slag component in which the slag ratio becomes the reference value or less is determined, It is possible to predict the adhesion of the inside of the furnace with high accuracy, to suppress the adhesion of the meeting, and to stably operate the heating furnace.

The method of restraining the adhesion of the heating furnace and the apparatus for restraining the adhesion of the heating furnace of the present invention are not limited to the above-described embodiments. For example, the average particle diameter based on the particle diameter distribution may be obtained as the coal form of the solid fuel. The average particle diameter may be measured as an additive property of the metal compound or the metal-containing compound (step S1, computing unit 9). Further, the solid fuel, the metal compound or the metal-containing compound to be used in the furnace may be selected in advance so that the average particle diameter of the metal compound or the metal-containing compound is smaller than the average particle diameter of the solid fuel.

Based compound or the metal-containing compound in the case where the amount of the metal-based compound or the metal-containing compound to be added is different from that of the metal-based compound or the metal- The smaller the average particle diameter of the compound, the smaller the adhesion rate. Therefore, particularly when the average particle diameter of the metal-based compound or the metal-containing compound is smaller than the average particle diameter of the solid fuel, the adhesion to the heating furnace can be effectively suppressed.

Next, a description will be given of a method for restraining the adhesion of the heating furnace according to the modified example of the present embodiment with reference to Fig. Fig. 7 is a step diagram showing the procedure of the rotation attachment restraining method of the heating furnace according to the present modification. In the following description of this modified example, the same contents as those of the method of suppressing the adhesion of the heating furnace according to the above-described embodiment will be omitted, and only different portions will be described.

In the method of suppressing the adhesion of the heating furnace according to the present modification, as shown in Fig. 7, the coal composition of each solid fuel to be used in the heating furnace is measured, and at the same time, The additive property of the metal-containing compound is measured (step S11).

Here, in this modified example, the average particle diameter based on the particle size distribution is determined as the coal shape of the solid fuel. As an additive property of the metal compound or the metal-containing compound, the average particle diameter and the like are measured in addition to the content of the method of inhibiting the adhesion of the heating furnace according to the above-described embodiment.

Next, based on the composition of the ash components of the plural kinds of solid fuels and the slag ratio indicating the ratio of the slag in the atmospheric gas composition and the predetermined atmospheric temperature out of a predetermined amount of the ash component calculated beforehand for the plural kinds of solid fuels (Step S12). The slag ratio in the heating furnace is set so that the composition of the slag component becomes equal to or lower than the reference value (step S12). The composition of the ash component and the slag ratio are measured or calculated in advance for a plurality of kinds of solid fuels in which a plurality of kinds of metal-based compounds having an average particle diameter or metal-containing compounds are added and mixed at a plurality of mixing ratios.

Here, in the present modification, the mixing ratio of a plurality of types of solid fuel, a metal-based compound or a metal-containing compound to be added to and mixed with a plurality of kinds of solid fuel, and a plurality of kinds of metal- Is used as this parameter. The composition of the ash components of a plurality of kinds of solid fuels in which a plurality of kinds of metal-based compounds or metal-containing compounds having an average particle diameter are added and mixed at a plurality of mixing ratios is determined so that the composition of the ash components of the plurality of solid fuels measured in step S11 And the composition of the inorganic component of the metal-based compound or the metal-containing compound. Then, by the thermodynamic equilibrium calculation, the slag ratio in the slag is obtained. A predetermined mixing ratio and a predetermined average particle diameter are calculated from a plurality of mixing ratios and plural kinds of average particle diameters so that the slag ratio in the slag becomes the value (reference value) of the determined slag ratio.

Finally, the predetermined mixing ratios of the plural kinds of solid fuels and the metallic compounds or metal-containing compounds to be added to and mixed with the plural kinds of solid fuels and the predetermined average particle size of the metal- Based on the diameter, the solid fuel and the metal-based compound or the metal-containing compound are mixed. Then, the mixture of the solid fuel and the metal compound or the metal-containing compound is pulverized and then supplied to the heating furnace as fuel (step S13).

Next, a description will be given of an anti-rotation device for a heating furnace according to the present modification with reference to Fig. Fig. 2 is a schematic view showing the apparatus for restraining rotation of the heating furnace according to the present modification. Fig. 2 is the same as the apparatus for restraining rotation of the heating furnace according to the embodiment described above. In the following description, the same components as those of the apparatus for restraining rotation of the heating furnace according to the above-described embodiment are not described here, and only the other components will be described.

In the present modified example, the computing unit 9 calculates the amount of coal to be used in the heating furnace (the water content of the solid fuel, the calorific value, the ash content, the composition of the ash components) (The moisture content, the inorganic content, the composition of the inorganic component, the average particle diameter, etc.) of the metal-based compound or the metal-containing compound are accumulated in advance as data 8. The operator 9 calculates the mixing ratio of a plurality of types of solid fuel and a plurality of types of metal-based compound or metal-containing compound calculator 9 to be added to and mixed with a plurality of types of solid fuel, Is used as a parameter. The calculator 9 calculates the composition of the ash components of a plurality of kinds of solid fuels to which a plurality of types of metal-based compounds or metal-containing compounds having an average particle diameter are added at a plurality of mixing ratios, The composition of the ash component, and the composition of the inorganic component of the metal compound or the metal-containing compound. Then, the operator 9 calculates the slag ratio in the rotor by the thermodynamic equilibrium calculation. Then, from a plurality of mixing ratios and a plurality of kinds of average particle diameters, a predetermined mixing ratio and a predetermined average particle diameter are calculated such that the slag ratio in the slurry falls below the determined reference value.

As described above, in the present modification, the method of restraining the adhesion of the heating furnace and the detachment preventing device are melted by the combustion in the heating furnace, floated on the air stream of the combustion air in the heating furnace and adhered to the furnace wall or the heat transfer tube group Which is a component of the slag. In this modified example, the slag ratio calculated for a plurality of kinds of solid fuels mixed with a plurality of types of metal-based compounds or metal-containing compounds having an average particle diameter as additives, and a plurality of kinds of solid fuels Based on the composition of the ash component and the composition of the inorganic component of the metal compound or the metal-containing compound, a predetermined mixing ratio is determined from a plurality of mixing ratios, and a predetermined average particle diameter is determined from a plurality of average particle diameters . Therefore, in the present invention, the slip characteristics are evaluated based on the slag ratio, which is a newly constructed evaluation index, and a proper mixing ratio is determined from a plurality of mixing ratios so that the slag ratio becomes the composition of the slag component that becomes the reference value or less , It is possible to predict the rotation adhesion in the heating furnace with high accuracy by determining a predetermined average particle diameter from a plurality of average particle diameters. As a result, it is possible to suppress the adhesion of the meeting, and it is possible to stably operate the heating furnace.

Example

Next, a description will be given of an embodiment using the method of restraining adhesion of the heating furnace and the detachment restraining device according to the above-described embodiment, with reference to Figs. 3 to 6 and Tables 1 and 2.

In the present embodiment, first, on the basis of the relationship between the slip ratio and the previously measured slip ratio, a slag ratio value (reference value) which is lowered to about 5 to 7% by weight or less is determined Will be described with reference to Fig. 3 and Table 1. Fig.

In this specific example, under the condition that the sum of the heat input amount of the city gas for heating and the pulverized coal for heating is constant at 149 kW in the pulverized coal combustion test (400 mm in the inside diameter of the furnace and the effective height in the furnace at 3650 mm) Experiments were conducted using these five different kinds of pulverized coal. In the experiment, the feed amount was adjusted by mixing single or plural types of pulverized coal so that the input heat quantity of the five pulverized coal was constant at 60 kW. Then, the pulverized coal having the adjusted supply amount is burned in the burner provided in the furnace along with the combustion air, and the turn attaching probe is inserted in the downward direction and held for 100 minutes, thereby checking the meeting attaching rate attached to the surface of the turn attaching probe. Here, the atmospheric temperature in the furnace of the turn fitting probe insertion portion is about 1300 DEG C, which is the same as the temperature at which the turn sticking phenomenon occurs in the actual can heating furnace. In addition, the temperature is adjusted by water-cooling the inside so that the surface temperature of the turn attach probe is about 500 캜. Table 1 shows the properties of the five types of pulverized coal used in the experiment of the specific example of the relationship between the slag ratio and the slip adhesion ratio.

Then, based on the characteristics of the fine coal as shown in Table 1, a state in which a certain amount of the reaction is thermodynamically the most stable in a certain condition (temperature and atmosphere gas composition), that is, a state in which the free energy? The composition or phase of the state is determined by thermodynamic equilibrium calculation, whereby the slag ratio of the pulverized coal used as the fuel in the experiment is calculated. In this embodiment, the temperature was 1300 占 폚, and the composition of the atmospheric gas was O ₂ : 1 vol%, CO ₂ : 19 vol%, and N ₂ : 80 vol%. Fig. 3 shows the relationship between the slag ratio and the rolling adhesion ratio in the concrete examples.

As shown in Fig. 3, in this embodiment, the slag ratio is 50 to 60 wt%, the slag adhesion rate is 5 to 7 wt% or less, and when the slag ratio is 50 to 60 wt% or more It is evident that the rate of sticking of the rings increases sharply. Therefore, if the reference value of the slag ratio is determined to be 50 to 60% by weight or less, adhesion of meeting can be suppressed. Thus, in this embodiment, the reference value of the slag ratio is determined to be 50 to 60 wt% or less. Further, in this specific example, in evaluating the slag ratio based on the slip adhesion rate, a mixture obtained by mixing two pulp powders out of five pulp powders by changing the mixing ratio was used, but the present invention is not limited thereto . The slag ratio may be evaluated by using a mixture obtained by mixing a plurality of kinds of pulverized coal and a plurality of kinds of metal compounds or metal-containing compounds in different mixing ratios. Further, in this specific example, evaluation is performed using pulverized coal other than the pulverized coal described below, but the present invention is not limited to this, and the pulverized coal described below may be used for the evaluation.

Next, with reference to Fig. 1 described above, the procedure of the anti-rotation attachment method of the heating furnace according to the present embodiment will be described. In this embodiment, under the condition that the sum of the heat input amount of the city gas for heating and the coal powder is constant at 149 kW in the pulverized coal combustion test (the inside diameter of the furnace is 400 mm and the effective height in the furnace is 3650 mm) Experiments were carried out using five different kinds of pulverized coal (solid fuel).

First, in the first and second embodiments, the coal properties of each solid fuel to be used in the heating furnace are measured, and the additive properties of the metal compound or the metal-containing compound to be added to the solid fuel are measured (step S1). Table 2 shows the characteristics of the five types of pulverized coal, coal A, B, C, D and E used in the first and second embodiments. As the metal compound or metal-containing compound, magnesium oxide (MgO) powder having a purity of 99% or more, or aluminum oxide (Al ₂ O ₃ ) powder having a purity of 99% or more is used.

Next, based on the composition of the ash components of the plural kinds of solid fuels and the slag ratio indicating the ratio of the slag in the atmospheric gas composition and the predetermined atmospheric temperature out of a predetermined amount of the ash component calculated beforehand for the plural kinds of solid fuels And a predetermined blending ratio of the composition of the soot component in which the slag ratio in the heating furnace is equal to or lower than the reference value is determined (step S2). The composition of the ash component and the slag ratio are measured or calculated for a plurality of kinds of solid fuels to which a metal compound or a metal-containing compound is added at a plurality of mixing ratios.

In this embodiment, among the coal shown in Table 2, the slag ratio of the pulverized coal of coal B, C, D and E whose softening point is lower than 1300 ° C is calculated. That is, in this embodiment, a certain amount of rotation is thermodynamically the most stable state under certain conditions (temperature and atmosphere gas composition), that is, the free energy of the Gibbs (? G) Is calculated by thermodynamic equilibrium calculation. In this embodiment, the thermodynamic equilibrium calculation is performed at a temperature of 1300 ° C and an atmosphere gas composition of O ₂ : 1 vol%, CO ₂ : 19 vol%, and N ₂ : 80 vol%. In the first embodiment, magnesium oxide (MgO) powder having a purity of 99% or more as a metal compound or a metal-containing compound to be added to each pulverized coal is mixed at a plurality of mixing ratios (in this first embodiment, 5, 10, 25 and 50% by weight based on the weight of the slag), and the transition of the slag ratio is calculated by thermodynamic equilibrium calculation. Likewise, in the second embodiment, aluminum oxide (Al ₂ O ₃ ) powder having a purity of 99% or more as a metal compound or a metal-containing compound to be added to each pulverized coal is mixed at a plurality of mixing ratios (In the second embodiment, 0, 5, 10, 25, and 50% by weight), and the transition of the slag ratio is calculated by thermodynamic equilibrium calculation.

4 is a relationship, of the rotating components in the MgO content of the slag ratio in the first embodiment Figure 5 shows a relationship between the times of the Al ₂ O ₃ component of the second embodiment The content of the slag rate. The abscissa of FIG. 4 shows the MgO content ratio in the ash, and the abscissa of FIG. 5 shows the Al ₂ O ₃ component content in the ash. Each value is expressed as a value obtained by adding the percent by weight of magnesium oxide or aluminum oxide of the recycled pulverized coal shown in Table 2 and the percent by weight of the mixed metal compound or metal containing compound (magnesium oxide or aluminum oxide) have.

From Figs. 4 and 5, it can be seen that the slag ratio decreases with the increase of the MgO content ratio or the Al ₂ O ₃ component content in the slag for any fly ash.

Based on Figs. 4 and 5, a predetermined mixing ratio in which the slag ratio in the furnace is lower than the reference value, that is, 50 to 60 wt% or less as shown in the above specific example, is determined. In the case of the first embodiment, the amount of the coal B, the amount of the coal D, the amount of the coal D, the amount of the coal D, the amount of the coal D, 50% by weight of MgO, 50% by weight of coal E and 50% by weight of MgO is determined as a predetermined mixing ratio at which the slag ratio is 50 to 60% by weight or less. In the second embodiment, if the coal B of the Al ₂ O ₃ 50 per wt% +, coal C of times + Al ₂ O ₃ 50% by weight, of coal D times + Al ₂ O ₃ 50% by weight, once + Al ₂ O ₃ 25% by weight of coal E, once + Al ₂ O ₃ 50% by weight of coal, E, is determined as a predetermined mixture ratio of the slag, the rate at which greater than 50 to 60% by weight.

Finally, based on a predetermined mixing ratio of the plurality of kinds of solid fuels calculated in step S2 and the metal-based compound or metal-containing compound to be added to and mixed with a plurality of kinds of solid fuels, the solid fuel and the metal- . After the solid fuel and the mixture of the metal compound and the metal-containing compound are pulverized, they are supplied to the heating furnace as fuel (step S3).

In order to examine the effectiveness of the present embodiment described above, an experiment was conducted to determine the adhesion rate of the fine coal powder in which the magnesium oxide (MgO) powders used in the first embodiment were mixed at a plurality of mixing ratios. In the experiment, two types of pulverized coal (coal A, B) having different compositions of the fly ash in the five types of pulverized coal are used, and the supplied amount of pulverized coal is adjusted so that the heat input amount of the pulverized coal becomes constant at 60 kW. Then, the pulverized coal obtained by adding and mixing the metal compound or the metal-containing compound at a plurality of mixing ratios was burned together with the combustion air with the burner installed in the furnace, and the turn attaching probe was inserted in the downward direction and held for 100 minutes, The rate of meeting attachment on the surface is investigated. Here, the atmospheric temperature in the furnace of the turn fitting probe insertion portion is about 1300 DEG C, which is the same as the temperature at which the turn sticking phenomenon occurs in the actual can heating furnace. In addition, the temperature is adjusted by water-cooling the inside so that the surface temperature of the turn attach probe is about 500 캜. For comparison, an experiment is also conducted on coal A to which no metal compound or metal-containing compound is added. Experiments were also conducted by adding magnesium oxide (MgO) powder having a purity of 99% or more as a metal compound or a metal-containing compound to coal B at a mixing ratio of 25% by weight or 50% by weight based on the weight of the coal B .

Fig. 6 shows the relationship between the slag ratio and the slip adhesion ratio, which is the result of the experiment of the first embodiment. As shown in FIG. 6, in the case where 25% by weight or 50% by weight of MgO powder is added to coal B so that the slag ratio is 50 to 60% by weight or less in the first embodiment, Is about 5 to 7% by weight or less. On the other hand, when the MgO powder is not added to the coal B, the slag ratio is about 95 wt%, and the rate of adhesion is 10 wt% or more. From this, it is apparent that the slag ratio is also increased when the slag ratio is high. In addition, even when the MgO powder is not added to the coal A, the slag ratio is about 40% by weight and the recoat rate is 5 to 7% by weight or less. It is apparent that when the slag ratio is low, the adhesion rate is also lowered. Therefore, it can be seen that the coalescence can be suppressed in the coal A without adding a metal compound such as MgO powder or a metal-containing compound.

From this, the reference value of the slag ratio is set to 50 to 60 wt% or less, and with reference to Figs. 4 and 5, the ratio of the MgO content in the slag or the Al ₂ O ₃ component It can be seen that the adhesion of the plating can be suppressed by adjusting the mixing ratio of the MgO powder or the Al ₂ O ₃ powder to be added to the pulverized coal.

Next, a description will be given of a third embodiment using the method of restraining the adhesion of the heating furnace according to the above-described modified example and using the rotation restraining suppressing device with reference to Figs. 8 and 9. Fig.

First, according to Fig. 1, a description will be given of the procedure of the anti-rotation attachment method of the heating furnace according to the third embodiment. In the third embodiment, as in the first and second embodiments described above, the reference value of the slag ratio is determined to be 50 to 60 wt% or less. In the third embodiment, in the same manner as in the first and second embodiments described above, in the pulverized coal combustion test (400 mm in diameter in the furnace, effective height in the furnace: 3650 mm) Under the condition that the total amount of heat is constant at 149 kW, the experiment is carried out using five types of pulverized coal (solid fuel) having different composition of the sintered component.

First, in the experiment of the third embodiment, the coal properties of each solid fuel to be used in the heating furnace are measured, and the additive properties of the metal compound or the metal-containing compound to be added to the solid fuel are measured (step S11 ).

In the third embodiment, coal B shown in Table 2 is used. Fig. 8 shows the particle size distribution of coal B; Based on Fig. 8, the average particle diameter of the coal B (the particle diameter when the cumulative weight is 50 wt%) is 6.8 mu m. In the third embodiment, magnesium oxide (MgO) is used as the metal compound or the metal-containing compound. The average particle diameters of a plurality of kinds of magnesium oxide (MgO) particles are prepared to be 10 mu m (expressed in square), 5 mu m (expressed in triangle), and 0.2 mu m (expressed in circle).

Next, based on the composition of the ash components of the plural kinds of solid fuels and the slag ratio indicating the ratio of the slag in the atmospheric gas composition and the predetermined atmospheric temperature out of a predetermined amount of the ash component calculated beforehand for the plural kinds of solid fuels And a predetermined mixing ratio and a predetermined average particle diameter of the composition of the soot component in which the slag ratio in the heating furnace is equal to or lower than the reference value are determined (step S12). The composition of the ash component and the slag ratio are measured or calculated in advance for a plurality of kinds of solid fuels in which a plurality of kinds of metal-based compounds having an average particle diameter or metal-containing compounds are added and mixed at a plurality of mixing ratios.

In the third embodiment, the addition weight (plural kinds of mixing ratios) of magnesium oxide (MgO) is 0 wt% (no addition), 25 wt%, and 50 wt% with respect to the weight of the coal B, respectively. Fig. 9 shows the results of the experiment relating to the third embodiment as a relation between the slag ratio and the slip adhesion ratio. In Fig. 9, the turnover percentage is plotted at three different mixing ratios for each particle diameter of MgO added. The mixing ratio of MgO is 50 wt%, 25 wt%, and 0 wt% (no addition) in order from the low slag ratio. From the results shown in Fig. 9, it can be seen that as the addition weight of MgO is the same, the smaller the particle diameter of MgO (5 占 퐉 or less), the smaller the adhesion rate becomes, and the antiadhesive effect becomes larger. In particular, it can be seen that when the average particle diameter of MgO is smaller than the average particle diameter of the coal B, the adhesion to the heating furnace can be suppressed effectively.

In the third embodiment, the average particle diameter of the magnesium oxide (MgO) particles is 5 mu m or less and the mixing ratio is 50 wt% or 25 wt% so that the slag ratio is 50 to 60 wt% or less .

Finally, the predetermined mixing ratio of the plural kinds of solid fuels calculated in the step S12 and the metallic compound or the metal containing compound to be mixed and added to the plural kinds of solid fuels and the predetermined average particle diameter of the metal compound or the metal- Based on this, a solid fuel and a metal-based compound or a metal-containing compound are mixed. After the mixture of the solid fuel and the metal compound or the metal-containing compound is pulverized, it is supplied to the heating furnace as fuel (step S13).

In the third embodiment, magnesium oxide (MgO) particles having an average particle diameter of 5 탆 or less are mixed at a mixing ratio of 50% by weight or 25% by weight. Thus, the coal B and the magnesium oxide (MgO) are mixed and supplied to the heating furnace as fuel.

Although the embodiments and the examples of the present invention have been described above, the present invention is not limited to the above-described embodiments, but can be variously modified within the scope of the claims. The present application is based on Japanese Patent Application (Japanese Patent Application No. 2010-159348) filed on July 14, 2010 and Japanese Patent Application (Japanese Patent Application No. 2011-138106) filed on June 22, 2011, The contents of which are incorporated herein by reference.

3: Fuel supply adjustment device (fuel supply adjustment device)
7: Heating furnace
9: Operator (Operator)

Claims (21)

A step of previously measuring a composition of each of the plural kinds of solid fuels and a composition of an inorganic component of a metal compound or a metal containing compound to be mixed and added as an additive to the plural kinds of solid fuels,
Wherein the metal-based compound or the metal-containing compound is added and mixed at a plurality of mixing ratios of the plural kinds of solid fuels in which the metal-based compound or the metal-containing compound is mixed at a plurality of mixing ratios, The slag ratio in the furnace is lower than a reference value on the basis of a predetermined atmospheric temperature among a predetermined amount of the ash component calculated in advance for the plural kinds of solid fuels and a slag ratio indicating a ratio of the slag in the atmospheric gas composition A step of determining a mixing ratio at which the composition of the ash component is obtained,
The mixture of the plurality of kinds of solid fuels and the metal-based compound or the metal-containing compound obtained by mixing the solid-state fuel and the metal-based compound or the metal-containing compound at the mixing ratio is supplied to the heating furnace And a step of controlling the temperature of the heating furnace. A step of previously measuring a composition of each of the plural kinds of solid fuels and a composition of an inorganic component of a metal compound or a metal containing compound to be mixed and added as an additive to the plural kinds of solid fuels,
Wherein a composition of a plurality of kinds of solid fuels obtained by mixing and mixing a plurality of kinds of metal-based compounds or metal-containing compounds having a mean particle diameter in a plurality of mixing ratios and mixing the plurality of kinds of solid- Based on a predetermined amount of the atmospheric temperature and a slag ratio indicative of the proportion of the slag in the atmospheric gas composition among a predetermined amount of the ash component calculated in advance for the plurality of kinds of solid fuels mixed and added at a plurality of mixing ratios A step of determining a blending ratio and an average particle diameter at which a composition of the ash component in which the slag ratio in the heating furnace is equal to or lower than a reference value is obtained,
A mixture of the plural kinds of solid fuels and the metal-based compound or the metal-containing compound obtained by mixing the plural kinds of solid fuels with the metal-based compound or the metal-containing compound having the average particle diameter at the above- And a step of supplying the heating furnace to the heating furnace. The method according to claim 1 or 2, wherein the main component of the metal element of the metal compound or the metal-containing compound is magnesium or aluminum. The method according to any one of claims 1 to 3, wherein the slag ratio is determined based on the composition of the ash component of the plurality of kinds of solid fuels to which the metal compound or the metal- Or calculated from the slag generated by heating at the atmospheric temperature and the atmospheric gas composition measured in advance for the plural kinds of solid fuels obtained by mixing or adding the metal compound or the metal containing compound at a plurality of mixing ratios Wherein the heating means is provided with a heating means for heating the heating furnace. The method according to claim 1 or 2, wherein the reference value is determined on the basis of the slip adhesion rate so that the slip adhesion rate with respect to the slag ratio becomes lower,
The slip adhesion ratio is calculated as a ratio of an actual adhesion amount to a collision amount to a turn attaching probe inserted in the heating furnace irradiated in advance,
Wherein said collision amount is calculated as a total amount of collision against a projected area of said turn attaching probe obtained from the shape of the furnace of said heating furnace and the amount of said solid fuel to be supplied, . The method according to claim 5, wherein the reference value is determined to be 50 to 60 wt% or less so that the adhesion rate is 5 to 7 wt% or less. The method according to claim 1 or 2, wherein the atmospheric temperature and the atmospheric gas composition are an atmospheric temperature and an atmospheric gas composition near the burner. 3. The method according to claim 1 or 2, wherein the atmospheric temperature and the composition of the atmospheric gas satisfy the following conditions: the highest atmospheric temperature in the design of the furnace and the atmospheric gas composition in the portion having such atmospheric temperature, Is the atmospheric gas composition having the highest atmospheric gas composition and the atmospheric temperature at the portion having such atmospheric gas composition. The method according to claim 1 or 2, wherein the average particle diameter of the metal compound or the metal-containing compound is smaller than the average particle diameter of the solid in the solid fuel. The method according to claim 2, wherein the metal-based compound or the metal-containing compound has an average particle diameter of 5 탆 or less. The composition of each of the ash components of the plurality of kinds of solid fuels and the composition of the inorganic component of the metal compound or the metal containing compound to be mixed and added as the additive to the plural kinds of solid fuels are previously measured and input, Containing compound is added and mixed at a plurality of mixing ratios, and the composition of the plural kinds of solid fuels mixed with the metal-based compound or the metal-containing compound at a plurality of mixing ratios, The composition of the ash composition in which the slag ratio in the heating furnace is equal to or smaller than the reference value is calculated based on the predetermined atmospheric temperature and the slag ratio representing the slag ratio in the atmospheric gas composition An operation unit for determining a mixing ratio to be obtained,
And a fuel supply amount adjusting unit for adjusting a supply amount of the plurality of kinds of solid fuels and the metal compound or the metal containing compound based on the mixing ratio determined in the calculating unit. A composition of each ash component of a plurality of kinds of solid fuels and a composition of an inorganic component of a metal compound or a metal containing compound to be added and mixed as an additive to the plural kinds of solid fuels are previously measured and inputted, Wherein the metal-based compound or the metal-containing compound having a plurality of kinds of average particle diameters and a plurality of the metal-based compounds or metal-containing compounds having a plurality of average particle diameters are mixed Based on the predetermined atmospheric temperature among the predetermined amount of the ash component calculated in advance for the plurality of kinds of solid fuels to be mixed and added, and the ratio of the slag to the slag in the atmospheric gas composition, The composition of the slag component in which the slag ratio of the slag component An operation section for determining the mixing ratio and the average particle diameter to be obtained,
And a fuel supply amount adjusting section for adjusting a supply amount of the plurality of kinds of solid fuels and the metal-based compound or the metal-containing compound based on the mixing ratio and the average particle diameter determined in the calculating section, Attachment restraining device. The apparatus according to claim 11 or 12, wherein the main component of the metal element of the metal compound or the metal-containing compound is magnesium or aluminum. 13. The method according to claim 11 or 12, wherein the slag ratio is determined based on the composition of the ash components of the plural types of solid fuels to which the metal-based compound or the metal-containing compound is added at a plurality of mixing ratios, Or calculated from the slag generated by heating at the atmospheric temperature and the atmospheric gas composition measured in advance for the plural kinds of solid fuels obtained by mixing or adding the metal compound or the metal containing compound at a plurality of mixing ratios Wherein the heating device is a heating device. 13. The method according to claim 11 or 12, wherein the reference value is determined so that the slip adhesion rate is lowered based on the slip adhesion ratio with respect to the slag ratio,
The slip adhesion ratio is calculated as a ratio of an actual adhesion amount to a collision amount to a turn attaching probe inserted in the heating furnace irradiated in advance,
Wherein the collision amount is calculated as a total amount of collision against the projected area of the turn stick probe obtained from the shape of the furnace of the heating furnace and the supply amount of the solid fuel, . The apparatus according to claim 15, wherein the reference value is determined to be 50 to 60% by weight or less so that the adhesion rate is 5 to 7% by weight or less. 13. The apparatus according to claim 11 or 12, wherein the atmospheric temperature and the atmospheric gas composition are an atmospheric temperature and an atmospheric gas composition near the burner. 13. The apparatus according to claim 11 or 12, further comprising a measuring section for measuring a temperature of the combustion chamber of the heating furnace and an atmospheric gas composition,
Wherein the atmospheric temperature and the atmospheric gas composition are a temperature of the combustion chamber of the heating furnace and an atmospheric gas composition measured by the metering section. The method according to claim 11 or 12, wherein the atmospheric temperature and the atmospheric gas composition are set so that the atmospheric temperature at the highest temperature in the design of the heating furnace and the composition of the atmospheric gas at the portion having such atmospheric temperature, Is the atmospheric gas composition having the highest atmospheric gas composition and the atmospheric temperature at the portion having such atmospheric gas composition. The apparatus according to claim 11 or 12, wherein the average particle diameter of the metal compound or the metal-containing compound is smaller than the average particle diameter of the solid fuel. The apparatus according to claim 12, wherein the metal-based compound or the metal-containing compound has an average particle diameter of 5 탆 or less.

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