JPH11171605A - Production of cement using waste material containing slightly water-soluble chlorine compound - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a production process for cement of high quality in spite of use of the waste containing slightly water-soluble chlorine compounds as a raw material. SOLUTION: The waste containing slightly water-soluble chlorine compound 1 is removed its iron scrap 3 and foreign substance 5 by means of a magnetic separator 2 and a fractionation sieve 4 and then charged into the cement kiln in the cement production plant. The chlorine that is taken into by the waste is vaporized in the kiln, and a part of the kiln exhaustion gas is sucked by the alkali by-pass unit 7 and the sucked kiln exhaustion gas is steeply cooled down in the temperature range of from 400-450 deg.C at which the chlorine compound forms. The chlorine taken in by the waste 1 is recovered as a dust containing water-soluble chlorine compound and removed, whereby the cement 8 of high quality from which chlorine is thoroughly separated is stably produced.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a cement using a main ash discharged from a refuse incinerator or the like, or a hardly water-soluble chlorine compound-containing waste such as shredder dust for home electric appliances or automobiles.

[0002]

2. Description of the Related Art In recent years, the tightness of land for final disposal sites has become a problem. Particularly in urban areas, the amount of waste generated has increased due to the concentration of population and industry. The situation is difficult to secure, and in order to prolong the life, it is required to establish a technology for effectively using waste instead of landfill. In view of such a situation, when recycling waste as a partial substitute for cement raw material, chlorine contained in the waste becomes a problem. When chlorine compound-containing waste is used as the cement raw material, the chlorine brought in by the waste in the cement kiln is vaporized and circulated and concentrated in the kiln and preheater together with volatile components such as alkali and sulfur, and the chlorine concentration in the system is reduced. When the melting point increases, a low-melting point compound is generated, which may cause clogging of the preheater and hinder stable operation of the kiln. In addition, the chlorine concentration in cement, which is a product, also increases, resulting in deterioration in quality. Therefore, the chlorine concentration of cement is specified to be 200 ppm or less in JIS standards.

[0003]

Therefore, it is necessary to remove chlorine from waste as a pretreatment. Most of the chlorine contained in municipal solid waste incineration fly ash etc. exists as water-soluble chloride, so it is possible to add water, elute this water-soluble chloride, and remove chlorine by filtration. It is. However, shredder dust from municipal solid waste incineration, shredder dust from home electric appliances, automobiles, etc. contains poorly water-soluble chlorine compounds. Use was difficult. The present invention has been made in order to solve such a problem, and a method capable of stably producing a high-quality cement while using a waste containing a poorly water-soluble chlorine compound as a raw material. The purpose is to provide.

[0004]

According to the present invention, there is provided a method for producing cement using a sparingly water-soluble chloride-containing waste, comprising the steps of:
Waste containing a poorly water-soluble chlorine compound is put into a cement kiln, kiln exhaust gas containing chlorine vaporized in the cement kiln is bled out of the cement kiln, and the bled kiln exhaust gas is rapidly cooled to a temperature below the melting point of the chlorine compound. This is a method of producing and removing a water-soluble chlorine compound by cooling. That is, a waste containing a poorly water-soluble chlorine compound is introduced into a cement kiln, and the chlorine brought in by the waste is vaporized at a high temperature in the kiln and efficiently removed to produce a cement.

In practice, foreign substances such as hardware and bulky substances are first removed from a waste containing a poorly water-soluble chlorine compound by a magnetic separator or a sieving apparatus, and the waste is used as a part of a cement raw material in a cement kiln. To Next, by a so-called alkaline bypass facility, for example, several tens% of exhaust gas containing chlorine and alkali components such as sodium and potassium brought in by the waste vaporized at a high temperature in the kiln is bled out from the housing at the kiln inlet and bled. The kiln exhaust gas is rapidly cooled to a temperature below the melting point of the chlorine compound, and collected as dust containing a water-soluble chlorine compound by a dust collector. In this way, the chlorine introduced into the waste is effectively removed, preventing the blockage of the preheater and the increase in the chlorine content of the cement product due to the low melting point compound, while preventing the waste containing the poorly water-soluble chlorine compound. Can be used as a cement raw material to produce cement.

The kiln exhaust gas is extracted at a rate of 10% or less, and the extracted kiln exhaust gas is rapidly cooled to a temperature not higher than the melting point of the chlorine compound. It can be separated into fine powder and the separated coarse powder can be returned into the cement kiln. In practice, first, foreign matter such as hardware and bulky matter is removed from waste containing a poorly water-soluble chlorine compound by a magnetic separator or a sieving device, and then the waste is put into a cement kiln as a part of a cement raw material. . Next, gas of 10% or less of the kiln exhaust gas is extracted from the kiln by a so-called chlorine bypass facility, and the extracted exhaust gas is rapidly cooled to a temperature equal to or lower than the melting point of the chlorine compound. Is separated into coarse powder and fine powder by a classifier, and the separated coarse powder is returned to the cement kiln. On the other hand, fine powder containing a large amount of chlorine compounds is sent to the downstream side of the classifier and discharged out of the system. The discharged dust is returned to the cement manufacturing process.

In this case, the bleed air amount of the chlorine bypass is 10%.
The degree of reduction of chlorine in the kiln exhaust gas reaches 90%, and the amount of bleed air is sufficiently 10% or less in consideration of economy and practicality. Further, since the extracted gas after the classification is returned to the kiln, the heat loss can be reduced as compared with the alkali bypass. Further, chlorine in dust generated in the cooling step is ubiquitous in the fine powder, and can be efficiently desalted by collecting the fine powder after classification at 5 to 7 μm, and the dust amount can be reduced.

When chlorine is concentrated and removed to a higher concentration using a chlorine bypass facility, the chlorine content of the collected dust is about 20%. The method of the present invention for removing chlorine is particularly effective for waste having a chlorine content of 20% or less.

Some chlorine compound-containing wastes contain both a water-soluble chlorine compound and a sparingly water-soluble chlorine compound. Therefore, using waste containing both such a poorly water-soluble chlorine compound and a water-soluble chlorine compound, removing foreign matter from the waste and removing the water-soluble chlorine compound by washing with water, and then removing the waste into a cement kiln You can also put it in. In practice, water is first sprayed simultaneously with the removal of foreign matter from waste by a sieving apparatus, or water is added to the waste from which foreign matter has been removed, and the water-soluble chlorine contained in the waste is removed. The compound is eluted and the slurry is filtered to remove water-soluble chlorine compounds. The wastewater at this time is discharged after removing harmful components such as heavy metals by providing a wastewater treatment facility. Next, the dewatered cake of the waste from which the water-soluble chlorine compound has been removed is put into a cement kiln having an alkali bypass facility or a chlorine bypass facility as a partial substitute for a cement raw material. Here, in the kiln and the preheater, part of the exhaust gas containing chlorine and alkali components such as sodium and potassium brought in by the poorly water-soluble chlorine compound remaining in the waste vaporized at a high temperature by an alkali bypass facility or a chlorine bypass facility. Air is extracted from the kiln inlet housing, and the extracted exhaust gas is rapidly cooled to a temperature equal to or lower than the melting point of the chlorine compound, and collected as dust containing a water-soluble chlorine compound.

In this way, the poorly water-soluble chlorine compounds that could not be removed by the water washing treatment are effectively removed.
A cement can be produced by using a large amount of waste as a cement raw material while preventing the preheater from being blocked by a low melting point compound and increasing the chlorine content of a cement product. In this case, equipment cost and running cost are higher than when chlorine is removed only by the alkali bypass facility or the chlorine bypass facility, but it is effective for use of waste containing a large amount of water-soluble chlorine compounds.

As the waste, municipal solid waste incineration ash can be used. The main ash discharged from the refuse incinerator is usually a substance containing a cement component such as Al ₂ O ₃ , SiO ₂ and CaO. The main ash contains about 3% of chlorine, of which about 50% of chlorine is present as a poorly water-soluble chlorine compound. Therefore, chlorine cannot be sufficiently removed by a simple method such as washing with water, and when used as a cement raw material, the amount of chlorine used has to be limited depending on the amount of chlorine brought in. However, according to the method of the present invention, chlorine brought in by the main ash can be sufficiently removed, and it can be used as a cement raw material in a large amount. Further, as the waste, electric appliances or automobile shredder dust can be used. Approximately 60% of the shredder dust of electric appliances and automobiles is flammable, and the remaining 40% of non-combustible is usually Fe ₂ O ₃ , SiO.
_2. Contains cement components such as CaO. In addition, such shredder dust contains a few percent of chlorine which is mostly present as an insoluble chlorine compound such as vinyl chloride. Therefore, by removing chlorine from the shatter dust according to the method of the present invention, it becomes possible to use the shatter dust of electric appliances and automobiles as a partial substitute for fuel or raw material in a cement production facility.

[0012] In order to carry out the method of the present invention, a cement production facility including a cement kiln having an alkali bypass unit or a chlorine bypass unit for removing vaporized chlorine is required. Further, a magnetic separator and / or a sieving device for removing foreign matter from the chlorine compound-containing waste is required. Further, a water washing tank that receives slurry on the downstream side of the sieving apparatus and a device that sprinkles water on the chlorinated compound-containing waste and elutes water-soluble chlorides in the chlorinated compound-containing waste,
Alternatively, a water washing tank with a stirring function to elute water-soluble chlorine compounds by adding water to the chlorine compound-containing waste after removing foreign substances, a filtration device for filtering and dewatering the slurry, and removing harmful components such as heavy metals from the wastewater to be harmless. Wastewater treatment equipment is required.

[0013]

Embodiments of the present invention will be described below with reference to the accompanying drawings. (A) Method by alkali bypass Chlorine causes deterioration of cement quality.
However, there is a standard that the chlorine content of cement is 200 ppm or less. Chlorine introduced from the cement raw material or fuel is volatilized and circulated and concentrated in the kiln preheater system, and a low melting point compound is formed, which causes the preheater to be blocked. In addition, the chlorine concentration of the cement, which is a product, also increases, which is a factor that causes quality deterioration.

[0014] Therefore, the waste water containing a poorly water-soluble chlorine compound is used in a cement production facility comprising a cement kiln having an alkali bypass facility. As shown in FIG. 1, a waste 1 containing a poorly water-soluble chlorine compound is first separated from a magnetic separator 2.
, Where iron scrap 3 is removed. Next, the waste 1 is introduced into the sieving apparatus 4, and the bulky material and the magnetic separator 2 are separated.
The foreign matter 5 such as coarse metal such as aluminum which cannot be removed by the above is removed.

The waste 1 from which foreign matter has been removed in this way
Is fed into a cement kiln as a partial substitute for raw materials in a cement production facility 6. The chlorine brought in by the waste 1 is vaporized at a high temperature in the kiln. Tens% of the kiln exhaust gas containing vaporized chlorine, sodium, and potassium is bled by the alkali bypass facility 7, and about 110 bled.
Kiln exhaust gas at a temperature of about 0 ° C. is introduced into a cooler, where cooling air from a fan is mixed to rapidly cool the exhaust gas to a temperature range of 400 to 450 ° C. where chlorine compounds are generated. At this time, the compound of the volatile component containing chlorine is coagulated and adsorbed on the surface of the dust due to the decrease in the gas temperature. Next, after spraying water from the spray tower to the gas and further cooling it to a temperature of about 150 ° C., the gas is collected by an electric dust collector, and the gas from which dust has been removed is discharged to the atmosphere. Thus, waste 1
The chlorine brought in is collected and removed as water-soluble chlorine compound-containing dust 9 by a spray tower and an electric dust collector.
On the other hand, from the cement kiln, high-quality cement 8 from which chlorine has been sufficiently removed is stably manufactured.

[0016] Thereby, the formation of the low-melting point compound prevents the play heater from being clogged, thereby preventing the stable operation of the cement kiln or increasing the chlorine content of the cement product. 1
Can be used in large quantities to produce high quality cement 8.

(B) Method Using Chlorine Bypass In FIG. 1, the chlorine bypass equipment 7 is used in place of the alkali bypass equipment 7 to effectively remove chlorine brought into the poorly water-soluble chlorine compound-containing waste 1 by chlorine bypass. is there. The chlorine bypass includes a step of extracting a part of the kiln exhaust gas from the kiln of the cement manufacturing facility 6, a step of rapidly cooling the extracted exhaust gas to a temperature equal to or lower than the melting point of the chlorine compound, and a step of classifying dust in the rapidly cooled exhaust gas. And a step of returning the separated coarse powder and exhaust gas to the kiln while sending the fine powder downstream of the classifier, wherein the ratio of the exhaust gas extraction amount is 0%. Beyond
10% or less, and the classification point of the classifier is 5 to 7 μm. In the method using the chlorine bypass, the extraction rate of the exhaust gas is smaller than that in the method using the alkali bypass, and the exhaust gas after the classification is returned to the kiln again, so that the calorific value loss can be reduced. In addition, the amount of dust can be reduced by collecting fine powder by the classifier, and it is possible to more efficiently remove the chlorine brought into the poorly water-soluble chlorine compound-containing waste 1.

The desalting method using the above-mentioned alkali bypass facility or chlorine bypass facility is inexpensive in equipment cost and running cost, and contains waste having a chlorine content of 20% or less and water-soluble chlorine compounds. It is especially effective for unfilled waste.

(C) Method of Using Waste Containing Both Poorly Water-Soluble Chlorine Compound and Water-Soluble Chlorine Compound As shown in FIG. 2, waste 10 containing both poorly water-soluble chlorine compound and water-soluble chlorine compound In this case, it is also effective to previously remove the water-soluble chlorine compound by washing with water. The waste 10 is first introduced into the magnetic separator 2, where iron scrap 3 is removed. Next, other foreign substances 5 are removed by the sieving device 4. The waste 1 from which the foreign matter 5 has been removed is introduced into a washing tank 11, where washing water 12 is added and stirred. Alternatively, the washing water 12 may be sprayed from above the sieve net by the sieving device 4 to receive the slurry in the washing tank 11. The slurry is mixed in the washing tank 11 to elute the water-soluble chlorine compound. Subsequently, the slurry is introduced into the filtration device 13 to perform filtration and dehydration.
The dewatered cake 15 thus obtained is put into a cement kiln of the cement production facility 6. In the cement kiln, the chlorine in the poorly water-soluble chlorine compound remaining in the dewatering cake 15 is vaporized, and the vaporized chlorine is extracted, cooled, and collected by the alkali bypass facility or the chlorine bypass facility 7 together with a part of the exhaust gas. And water-soluble chlorine compound-containing dust 9. Thereby, the high quality cement 8 from which chlorine is sufficiently removed is stably manufactured. Further, some heavy metals such as lead may be eluted in the drainage water 14 discharged from the filtration device 13. Therefore, the wastewater 14 is introduced into a wastewater treatment facility 17 including a pH adjustment device, a chelate addition device, a coagulation sedimentation device, a sedimentation filtration device, a chelate resin tower, and the like, and is discharged after being purified.

Compared to the case where the waste 10 is put into the kiln without washing with water, the amount of air extracted by the bypass facility can be reduced, the heat loss can be further reduced, and the amount of the water-soluble chlorine compound-containing dust 9 can be reduced. . Such a desalination method by washing the waste 10 with water is performed by the above (A) using only the alkali bypass facility or the chlorine bypass facility 7,
Although the equipment cost and the running cost are higher than the method (B), it is effective when the waste 10 contains a large amount of water-soluble chlorine compounds.

(D) Application to municipal waste incineration main ash and shredder dust The municipal waste incineration main ash contains cement components such as Al ₂ O ₃ , SiO ₂ , and CaO, and about 3% chlorine. About 50% of this chlorine is present as a poorly water-soluble chlorine compound. Therefore, according to the method of the present invention, first, foreign matter is removed from municipal solid waste incineration main ash by a magnetic separator or a sieving device, and the ash is introduced into a cement kiln, and chlorine introduced by the main ash is removed by an alkali bypass facility or a chlorine bypass facility. By doing so, high-quality cement can be stably manufactured. It is also effective to wash the main ash with water to remove the water-soluble chlorine compound, and then throw the main ash into a cement kiln and remove the chlorine brought in by the main ash with an alkali bypass facility or a chlorine bypass facility.
Approximately 60% of the electric appliances and automobile shredder dust is flammable, while the remaining 40% of non-combustible is Fe.
_It contains cement components such as ₂ O ₃ , SiO ₂ and CaO. Most of the chlorine compounds contained in this shatter dust are poorly water-soluble chlorine compounds such as vinyl chloride. Therefore, as in the case of the above main ash, foreign matter is first removed from this shredder dust using a magnetic separator or a sieving device, and then put into a cement kiln, and the chlorine brought in by the shredder dust is removed by an alkali bypass facility or chlorine bypass facility. By doing so, high-quality cement can be stably manufactured.

[0022]

Examples of the present invention will be described below. These are examples and do not limit the scope of the present invention. Example 1 A facility as shown in FIG. 1 was temporarily provided, and an experiment for producing cement was performed using a waste incineration main ash containing a poorly water-soluble chlorine compound as a raw material. Waste 1 consisting of refuse incineration main ash was treated by a pretreatment device including a magnetic separator 2 and a sieving device 4 at an input amount of 4.25 t / hr.
21% of the input amount, 893 kg / hr of iron scrap 3 and foreign substances 5 were removed, and 3.36 t / hr of cement raw material ashes were obtained. Analysis of the components of this main ash revealed that the water content was 28.8%, SiO _{2 was} 34.1%, and Al ₂ O ₃ : 1.
4.2%, CaO: 20.8%, MgO: 3.1%, C
l: 1.12%. The main ash pretreated in this manner is supplied to a cement kiln of a cement production facility 6 with a clinker production of 7000 t / day, and a chlorine bypass facility 7 is used to reduce kiln exhaust gas from the kiln inlet housing to about 2 to 2 kg.
While bleeding with a bleeding amount of 10% or less, 17.99 kg /
It was used as a partial substitute for clay at the input of t-cl. The amount of dust discharged from the chlorine bypass facility 7 is 0.
It was 986 kg / t-cl. When the quality of the manufactured cement was measured, the following results were obtained.

Example 1 JIS standard Cement strength Material age 3 days (N / mm ² ) 27.6 12.5 or more Cement strength Material age 7 days (N / mm ² ) 42.3 22.5 or more Cement strength Material age 28 days (N / mm ² ) 59.5 42.5 or more Chlorine content (%) 0.004 0.02 or less

By using the chlorine bypass equipment 7 as described above, chlorine brought in by the main ash can be effectively removed, and a large amount of the main ash can be used. Was sufficiently satisfied. The same effect was obtained by using an alkali bypass facility instead of the chlorine bypass facility.

Example 2 A facility as shown in FIG. 2 was temporarily installed, and an experiment was conducted to produce cement using waste incineration ash containing both a poorly water-soluble chlorine compound and a water-soluble chlorine compound as a raw material. The waste 10 consisting of the refuse incineration main ash was treated at a charging rate of 4.25 t / hr by a pretreatment device composed of a magnetic separator 2, a sieving device 4, a washing tank 11 and a filtration device 13. To elute the water-soluble chlorine compounds of the main ash,
Water was sprinkled by the sieving device 4, washing water was further added to the washing tank 10, and the main ash was stirred and washed with a total of five times the amount of the main ash, and then filtered by the filtration device 13. 19% of the input amount, 808 kg / hr of iron scrap 3 and foreign matter 5 were removed, and 3.44 t / hr of cement raw material main ash was obtained. When the components of the main ash after this water filtration were analyzed,
_{Moisture: 29.6%, SiO 2: 27.3} %, Al 2 O 3:
15.3%, CaO: 19.8%, MgO: 4.7%,
Cl: 0.997%. In addition, as a result of analyzing the chlorine content of the main ash before water washing collected in advance,
A value of 1.80% was obtained. Thus, it can be seen that by washing the main ash with water, 44.6% of the chlorine in the main ash could be removed.

By washing the main ash with water, water-soluble chlorine compounds contained in the main ash can be removed. Further, by putting the main ash into the cement kiln while operating the chlorine bypass facility, it can be removed by water washing. The chlorine in the main ash that had not been removed was also effectively removed, and the amount of the main ash used could be increased without increasing the chlorine content of the cement.

The waste water obtained by washing the main ash with water is 17 t / h.
r was discharged. An analysis of this wastewater for items specified in the Prime Minister's Ordinance that establishes wastewater standards showed that the pH was 12.75, lead was 0.06 mg / l, and copper was 0.1.
10 mg / l, zinc 0.06 mg / l, BOD 37 mg
/ L, COD 19 mg / l, nitrogen 9.16 mg / l, and all other items were not detected. As described above, only the value of the harmful component in the wastewater that is significantly lower than the reference value is detected, and it is possible to adjust only the pH and discharge the wastewater. However, in this embodiment, in order to further enhance the safety, the wastewater was introduced into a wastewater treatment facility 17 including a pH adjusting device, a chelating agent adding device, a decanter, a filter press, a chelating resin tower, and the like, and treated. .
As a result, the analysis value of items specified by the Prime Minister's Ordinance that sets wastewater standards was pH 7.6, and all other items were below the detection limit.

It should be noted that, in Example 1, similar results can be obtained by conducting an experiment using electric appliances containing a large amount of poorly water-soluble chlorine compounds instead of ash for incineration of refuse incineration as well as shredder dust of automobiles. It is.

[0029]

According to the method of the present invention, the following effects can be obtained. Foreign matter, such as iron scraps and other bulky substances, is removed from the poorly water-soluble chlorine compound-containing waste using a magnetic separator and a sieving device.Then, the waste is introduced into a cement kiln as a cement raw material, and chlorine brought into the kiln is vaporized. , This chlorine is extracted from the cement kiln together with a part of exhaust gas by an alkali bypass facility or a chlorine bypass facility,
By removing chlorine as a water-soluble chlorine compound,
Cement can be produced by using a large amount of hardly water-soluble chlorine compound-containing waste without causing deterioration of cement quality due to chlorine and without causing clogging of a kiln or a preheater. This method is particularly effective for wastes containing less than 20% chlorine and wastes containing a large amount of poorly water-soluble chlorine compounds. It can reduce main ash, electric appliances, and automobile shredder dust discharged from municipal solid waste incinerators. It is effective when used to produce cement.

In the case of waste containing both a poorly water-soluble chlorine compound and a water-soluble chlorine compound, water is added to the waste after the removal of foreign matters, and the water-soluble chlorine compound contained in the main ash is eluted. By filtering this slurry and using the obtained dewatered cake as a cement raw material, the amount of chlorine brought into the cement manufacturing process by waste can be reduced, and the amount of bleed air in the alkali bypass equipment and chlorine bypass equipment is also small. Heat loss can be reduced. Also, the amount of dust collected can be reduced. Waste water after washing is put into a cement kiln, and chlorine from hardly water-soluble chlorine compounds volatilized in the kiln is also removed by alkaline bypass equipment and chlorine bypass equipment, enabling stable production of high-quality cement. it can. The wastewater from which the waste was washed with water satisfies the numerical values specified by the Prime Minister's Ordinance that regulates the wastewater standards only by adjusting the pH, and it is possible to discharge the wastewater as it is. Can be enhanced.

[Brief description of the drawings]

FIG. 1 is a flowchart showing a cement production method according to an embodiment of the present invention.

FIG. 2 is a flowchart illustrating a cement manufacturing method according to another embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Waste containing water-insoluble chlorine compound 2 Magnetic separator 3 Iron scrap 4 Sieving device 5 Foreign material 6 Cement manufacturing equipment 7 Alkaline bypass equipment or chlorine bypass equipment 8 Cement 9 Dust containing water-soluble chlorine compound 10 Water-soluble soluble water-soluble chlorine compound Waste containing chlorine compounds 11 Rinse tank 12 Rinse water 13 Filtration device 14 Drainage 15 Dewatering cake 17 Drainage treatment device

Claims (5)

[Claims] 1. A method for producing cement using a cement kiln, wherein a waste containing a poorly water-soluble chlorine compound is introduced into the cement kiln, and a kiln exhaust gas containing chlorine vaporized in the cement kiln is discharged outside the cement kiln. Blend, cement production using poorly water-soluble chlorine compound-containing waste, characterized by generating and removing a water-soluble chlorine compound by rapidly cooling the extracted kiln exhaust gas to a temperature below the melting point of the chlorine compound. Method. 2. The kiln exhaust gas extraction rate is set to 10% or less, and the extracted kiln exhaust gas is rapidly cooled to a temperature equal to or lower than the melting point of a chlorine compound. The cement production method according to claim 1, wherein the coarse powder separated into fine powder is returned into the cement kiln. 3. A method for removing foreign matter from waste containing both a poorly water-soluble chlorine compound and a water-soluble chlorine compound and removing the water-soluble chlorine compound by washing with water, and then introducing the waste into a cement kiln. The method for producing cement according to claim 1 or 2, wherein 4. The cement production method according to claim 1, wherein the waste is municipal solid waste incineration main ash. 5. The method for producing cement according to claim 1, wherein the waste is an electric appliance or a shredder dust of an automobile.