JPH08283053A - Method of burning waste plastics in rotary kiln - Google Patents

Abstract

PURPOSE: To obtain a method of burning waste plastics by blowing them together with main fuel in a rotary kiln. CONSTITUTION: This method is provided with (a) a process for making the waste plastic particles to a fine flux flow and (b) a process for blowing the fine flux flow of the waste plastic particles from the upper side 18 of a blowing position 14 of the main fuel into the rotary kiln as fuel and burning them. Besides, they are blown so that a landing range of the waste plastic particles blown into the rotary kiln as a fine flux flow is preferably in the range of 1/10-2/3 flame length of the main fuel.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary kiln for producing quick lime, burned dolomite, Portland cement, etc. by using waste plastic which has not been used as a fuel, and a rotary kiln for incinerating municipal waste. It relates to a method of combustion by blowing.

[0002]

2. Description of the Related Art Waste plastic is a heat source having a high calorific value, but it is mainly discarded because the waste plastic has inferior combustibility as compared with other fuels such as pulverized coal. However,
From the viewpoint of environmental problems or effective utilization of resources, waste plastics have been gradually reused.

Focusing on the fact that waste plastic is a heat source having a high calorific value, a method for producing a cement clinker using waste plastic is disclosed in JP-A-46-15037. In this publication, the cement clinker can be manufactured at low cost by adding the waste plastic into the rotary kiln for manufacturing the cement clinker, but the specific method for adding the waste plastic into the rotary kiln is described in detail. No technology is disclosed.

Further, Japanese Patent Laid-Open No. 6-8247 discloses a method in which a fiber reinforced plastic is added to a rotary kiln for treatment. However, in this method, the fiber-reinforced plastic is crushed and added to particles of 90 μm or less, which is not economical. .

Further, Japanese Patent Publication No. 59-11545 discloses a method for producing Portland cement using municipal waste. In this method, a method is proposed in which municipal waste is preliminarily burned in a fluidized bed combustor to treat the municipal waste.

It is well known that Portland cement, quicklime or calcined dolomite is conventionally produced by using a so-called rotary kiln. The rotary kiln has a relatively large space through which the combustion gas passes with respect to the charged material, and is therefore convenient for burning various fuels.

FIG. 4 shows an outline of a rotary kiln facility for producing quicklime or calcined dolomite. The outline of the method for producing quicklime or burnt dolomite in the rotary kiln will be described below. The gemstone silo 1 containing gemstones of limestone and dolomite is supplied to the great preheater 2 for preheating the gemstone, preheated by the exhaust gas from the rotary kiln, and then the rotary kiln 6
Is charged to.

The rotary kiln is a cylindrical heating furnace in which a circular iron shell is lined with a refractory, and is rotating around a shaft at a constant speed. In the figure, the limestone charged from the inlet on the left passes through the rotating furnace and moves toward the outlet on the right. As shown in the figure, the rotary kiln has a raw material inlet of 3/100 to 4 / with respect to the outlet direction.
The limestone / dolomite charged is inclined upward by 100 and is rotated in the furnace while being fired, and is changed into quick lime or burned dolomite and moves toward the outlet.

At the outlet, a pulverized coal supply device 8 for supplying, for example, pulverized coal as fuel, is provided. The pulverized coal is blown into the furnace through a nozzle, burned by air, and the inside of the furnace is heated to 1000 ° C. Hold at the above high temperature. Due to the heat generated by the combustion of this pulverized coal, limestone and dolomite are calcined and converted into quick lime or burned dolomite.

Air for combustion of pulverized coal passes through a great cler for cooling discharged quicklime or burnt dolomite for heat exchange, while cooling hot quicklime or burnt dolomite on the other hand. In the above, the air having a high temperature is blown into the rotary kiln from the outlet side and becomes a supply source of air for burning the pulverized coal.

The temperature inside the rotary kiln is about 6 at the outlet side.
The temperature is around 00 ° C, and especially the part with the flame generated when pulverized coal burns reaches 1500 ° C or higher, and the temperature decreases with the decomposition reaction of limestone / dolomite. That is, on the gas outlet side, the temperature drops to about 1000 ° C.

The exhaust gas at a high temperature of about 1000 ° C. preheats the limestone and dolomite placed on the above-mentioned great preheater, releases a part of the heat there, and then passes through the waste heat boiler 3 and further the dust collector 4 After passing through the wet type dust collector 5, it is discharged to the outside.

The above is an outline of the rotary kiln facility for producing quicklime or burned dolomite. Conventionally, pulverized coal is mainly used as fuel in a rotary kiln, and heavy oil may be used as a part. However, these fuels are all expensive, and it is required to produce quick lime or calcined dolomite at a lower cost.

These pulverized coals have about 6000 kcal / k.
g, heavy oil has a calorific value of about 10,000 kcal / kg. On the other hand, waste plastic is about 10,000 kcal
Since it has a heat capacity of about / kg, it may be a valuable heat source along with pulverized coal.

However, waste plastics are usually obtained in the form of particles, and as described above, they are not easily burned, so that they have been conventionally discarded. A large amount of wastes such as polyethylene, polypropylene, polystyrene and polyvinyl chloride are currently generated as waste plastics. Therefore, it is required to use these as a heat source and, on the other hand, to use this inexpensive plastic to produce quicklime, calcined dolomite, Portland cement and the like at low cost.

[0016]

SUMMARY OF THE INVENTION In the present invention, as described above, in order to produce quicklime / calcined dolomite or Portland cement, which is important in the steel industry or other chemical industries, at a lower cost, it is conventionally simply discarded. The purpose is to blow the waste plastic that was used as a fuel into the rotary kiln and burn it efficiently.

However, unlike the fuel such as heavy oil and pulverized coal, the problem in using the waste plastic particles as a fuel is that it needs to be thermally decomposed before burning, and thus it is difficult to burn it easily. There is a problem.

Further, in order to completely combust in the rotary kiln and utilize the combustion heat, it is completely completed within a short residence time in the furnace (generally, the gas residence time in the furnace is about 10 seconds or less). There is a problem that the heat generated by burning must be used effectively. Therefore, in order to sufficiently burn the waste plastic particles in a short residence time in the furnace and utilize the heat of combustion, it is necessary to select an appropriate size of the waste plastic particles.

Further, there is a problem with the method of charging the waste plastic into the rotary kiln. Further, there is a problem in which position of the rotary kiln is charged in order to more completely burn the waste plastic and burn it efficiently.

[0020]

[Means for Solving the Problems]

(1) The invention of claim 1 provides a method for burning waste plastic in a rotary kiln, which comprises the following steps. (A) a step of making waste plastic particles into a fine bundle flow,
(B) A step of injecting the fine bundle flow of the waste plastic particles as fuel into the rotary kiln from above the main fuel injection position and burning it.

(2) According to the second aspect of the invention, the waste plastic particles blown into the rotary kiln as a fine bundle flow are blown so that the landing range is within the range of 1/10 to 2/3 of the flame of the main fuel. A method for burning waste plastic in a rotary kiln according to claim 1, is provided.

(3) The invention of claim 3 is characterized in that the landing range of the waste plastic particles is in the fourth quadrant of the cross section of the rotary kiln rotating clockwise. To provide a method for burning waste plastic in a rotary kiln.

(4) The invention of claim 4 is characterized in that the waste plastic particles blown into the rotary kiln as a fine bundle flow into the flame of the main fuel so as to come into contact with or cross the flame of the main fuel. A method for burning waste plastic in a rotary kiln according to any one of items 1 to 3 is provided.

(5) The invention of claim 5 is characterized in that the waste plastic particles are polyethylene, polypropylene, polystyrene having a particle diameter of 20 mm or less, or a mixture of two or more thereof. A method for burning waste plastic in a rotary kiln as described in 1 above is provided.

(6) The invention of claim 6 is characterized in that the waste plastic particles are polyvinyl chloride having a particle diameter of 10 mm or less, and the waste plastic in the rotary kiln according to any one of claims 1 to 4 is A combustion method is provided.

[0026]

As described above, it is necessary to determine the basic conditions for burning waste plastic particles in the rotary kiln in a short time. Therefore, the following preliminary experiments were conducted. Waste plastic particles having a diameter of 5 to 20 mm were collected, and the time taken to gasify and burn when the temperature was held at 1000 ° C. was investigated. The time to complete combustion of waste plastic particles in a small experimental furnace in various atmospheres with different oxygen concentrations was investigated.

As a result, particles of polyethylene, polypropylene, polystyrene or the like have an oxygen concentration of 5 vol at 1000 ° C. in the furnace atmosphere if the diameter is within 20 mm.
It was confirmed that when it was more than 5%, it was gasified within 5 seconds and completely burned. However, it was confirmed that polyvinyl chloride gasifies completely within 5 seconds when the oxygen concentration of the atmosphere in the furnace is 1000 vol. It was

From the above, the residence time of the gas in the rotary kiln having a length of about 50 m is usually 1 as described above.
Within 0 seconds, usually 7 to 8 seconds, so polyethylene,
Particles of polypropylene, polystyrene, etc. have a diameter of 20 mm
If it is within the range, the diameter of polyvinyl chloride particles is 10 mm
In the following cases, it was confirmed that each gas was sufficiently gasified and burned in the rotary kiln.

Next, an investigation was conducted on how to burn the waste plastic in a rotary kiln. Figure 1 shows the calculation results of the furnace temperature and the distribution of oxygen concentration in the combustion gas in the rotary kiln. It has been confirmed that this calculation result agrees with the actual measurement result. Normally, the rotary kiln has a length of about 50 m.
For example, in the case of production of quick lime or calcined dolomite, the temperature of the furnace gas at the inlet of raw material limestone / dolomite is about 600 ° C at the outlet, 1000 ° C at the place of 2 m, and about 1000 ° C at the place of 10 m. When the temperature rises above 1500 ° C, the temperature gradually decreases toward the entrance of the limestone / dolomite, reaching about 900 ° C.

On the other hand, limestone and dolomite, which are solid charges, are partially preheated and charged, so that 900 ° C. is introduced at the inlet.
The decomposition reaction is gradual and gradually reaches a temperature of more than 1000 ° C. at a point about 10 m from the entrance to the decomposition reaction, and the decomposition reaction is sufficiently changed to quicklime or burnt dolomite, which is discharged from the outlet.

On the other hand, the oxygen concentration in the furnace is 21 vol% because air is supplied at the outlet, but the fuel blown into the furnace from the outlet side, for example, pulverized coal, burns and the oxygen concentration gradually decreases. The oxygen concentration is about 2 vol% in the vicinity of about 15 m from the outlet.

In order to sufficiently burn the waste plastic in such a situation, the waste plastic should be added in a range where the oxygen concentration exists at least to some extent,
It is necessary to burn it completely. Therefore, the position where the waste plastic is blown into the furnace together with the pulverized coal, which is the main fuel,
Methods and the like are extremely important issues for using waste plastics as fuel.

This point will be described with reference to FIG. Figure 2 (a)
Shows a schematic vertical section near the exit of the rotary kiln. 2 (a), the pulverized coal which is the main fuel at the outlet of the rotary kiln 6 is blown into the furnace having a substantially circular cross section through the pulverized coal blowing nozzle 14, and at this time, the flame 16 is formed by the combustion of the pulverized coal. It This length L ₁ is, for example, about 15 m in consideration of oxygen concentration and gas temperature in the furnace. This point was confirmed by the ash adhesion state in the rotary kiln and the visual observation inside the furnace through the observation window.

On the other hand, the waste plastic has a diameter of 2 as described above.
Since it is a solid particle of 0 mm or 10 mm or less,
In order to burn in the rotary kiln, it is blown into the furnace at a constant initial velocity as a fine bundle flow from the waste plastic blowing nozzle 18 located near the outlet. At this time, since the solid particles do not burn instantaneously, some of them fall onto the bottom of the rotary kiln while burning along a predetermined trajectory 180. The landing point is L ₂ .

First, in order to sufficiently burn the waste plastic, it is premised that the waste plastic is blown as a fine bundle flow above the main fuel. That is, it is necessary to blow a fine bundle of waste plastic particles as fuel into the rotary kiln from above the main fuel injection position and burn it.

Next, as described above, since the already oxygen concentration in L ₁ or more is around 2 vol%, the landing point L ₂ on the oxygen concentration of about 5 vol% 2/3 of L ₁ Must be within. The minimum value of L ₂ is preferably about 10% of L ₁ . This is because if the waste plastic particles fall too close to the outlet, the temperature is low and they are discharged unburned.

Next, a further investigation was conducted on the desired blowing position. FIG. 2B shows the inside of the furnace in the AA cross section of FIG. In the figure, since the furnace body is rotating in the clockwise direction (the direction of the arrow), the solid charge 2
0 exists in a state of being biased to the position of the third quadrant in the figure.

Further, in order to efficiently burn the waste plastic blown into the furnace through the nozzle 18, the following conditions are desirable. In order to promote faster combustion, a waste nozzle is made into a fine bundle flow by a blowing nozzle, and the fine bundle flow forms a flame 1 formed by pulverized coal.
It is desirable to drop 6 so that it touches or crosses.
This is because the waste plastic particles are heated by the flame to promote rapid combustion.

Normally, in blowing pulverized coal, the flame is rotated, for example, clockwise as shown in the figure.
Therefore, when the waste plastic blowing nozzle 18 is positioned above the pulverized coal blowing nozzle, the trajectory of the waste plastic passes through the trajectory shown by the dotted line in the figure and, as shown in FIG. 2B, the fourth quadrant in the furnace. It falls to and lands. When dropped in this way, the particles of the waste plastic that have landed do not mix with the solid charge quicklime or Portland cement, so that the product does not mix with the waste plastic and its quality is maintained. It will be.

As a result of various preliminary experiments, the blowing amount of the waste plastic was 50% of the total calorific value necessary for producing quicklime, calcined dolomite, Portland cement and the like.
Up to waste plastic can be used. This is because if more waste plastic is used, unburned waste plastic remains in the product, which is not desirable.

Next, a device for blowing waste plastic into the rotary kiln as a fine bundle flow as described above will be briefly described. FIG. 3 shows an outline of the waste plastic blowing device. In the figure, waste plastic is loaded in the hopper 102, passes through the gate 104, and is dropped by the rotary valve 106 into the injection unit 108 in a predetermined amount within a predetermined time.

The dropped solid waste plastic is pneumatically sent from the blower 110 to the pipe 113 from the injection unit 108 by air. The waste plastic that has passed through the pipe 113 passes through the nozzle 18 and is injected into the furnace. The nozzle 18
It is protected by a gas cooling pipe or a water cooling pipe 116 on the outside thereof, and the outside of the water cooling pipe 116 is kept warm by, for example, a protection pipe 118 made of a refractory material.

The reason for this is that the hood 13 is provided on the exit side of the rotary kiln, and it is considered that the air preheated through the hood 13 enters the hood from below and then enters the rotary kiln. Is. That is, it prevents the waste plastic particles in the nozzle 18 from being melted in the tube by the preheated air entering from below.

Incidentally, such a blowing device for waste plastic particles is an example, and the present invention is not limited to such a device. The type of waste plastic may be any of polyethylene, polypropylene, polystyrene, polyvinyl chloride, etc., as described above.

The waste plastic particles having a maximum diameter of 20 mm can be used. From the above points, the diameter of the nozzle is 3 of the particles of waste plastic.
About 4 times is desirable. That is, if the diameter of the waste plastic particles is 10 mm, the inner diameter of the blowing nozzle is 30 to
About 40 mm is required.

[0046]

EXAMPLES In the examples, the total length is about 5 as shown in Table 1.
Experiments were carried out by injecting waste plastic particles as fuel in a 5 m rotary kiln. In this device, pulverized coal was mainly used as the main fuel and some heavy oil was used. Table 2 shows the operation test results.

In this rotary kiln, quick lime was produced for 400 tons per day, and other fuels shown in the table were used. 240 waste plastic as case 1
Injecting kg / h, in case 2, about 410k
At least 24 hours of operation was carried out by blowing in g / h.

At this time, considering the heat generation due to the combustion of the waste plastic, the main fuel corresponding to that amount was reduced.
Calculating from the amount of heat generation, the amount of waste plastic blown (mixing rate) is 10% in case 1 and 18% in case 2. In the table, the decomposition rate is the percentage of limestone that has turned into quick lime. From the results in this table, the concentration of the combustion gas at the charging inlet did not change significantly, and a good product was obtained even when the decomposition rate was taken into consideration. Further, as a result of analyzing the component composition of the exhaust gas at the charging port, the hydrocarbon composition was about 10 vo, as in the normal operation.
It was 1 · ppm.

[0049]

[Table 1]

[0050]

[Table 2]

[0051]

As described above, according to the method of the present invention, waste plastic particles can be burned sufficiently by adding the waste plastic particles in a proper manner and at a proper place in the rotary kiln, and the conventional method can be used. The product is obtained. Moreover, since the waste plastic is low in cost, it was able to greatly contribute to the reduction of the production cost. Therefore, while it was possible to effectively use the waste plastics that were mainly discarded conventionally as a heat source, it was possible to contribute to the reduction of wastes, and it was possible to prove that this is an extremely environmentally effective invention. .

[Brief description of drawings]

FIG. 1 is a diagram showing distributions of gas composition, temperature and the like in a rotary kiln.

FIG. 2 is a diagram showing a trajectory of a flame and a motion of injected waste plastic particles in a rotary kiln.

FIG. 3 is a schematic view of a waste plastic particle blowing device used in the present invention.

FIG. 4 is a diagram showing an outline of a rotary kiln facility for producing quicklime.

[Explanation of symbols]

 1 Gemstone silo 2 Great preheater 3 Waste heat boiler 4 Dust collector 5 Wet dust collector 6 Rotary kiln 8 Pulverized coal supply device 14 Pulverized coal blowing nozzle 18 Waste plastic blowing nozzle 20 Quick lime / burned dolomite

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hiroyasu Ito 1089 6 Horiime-cho, Sano City, Tochigi Prefecture (72) Inventor Susumu Isozaki 1-2 1-2 Marunouchi, Chiyoda-ku, Tokyo 72) Inventor Terufu Terufu Marunouchi 1-2-2 Nihon Steel Pipe Co., Ltd., Chiyoda-ku, Tokyo (72) Inventor Takehiko Aoki 1-2-1 Marunouchi Chiyoda-ku, Tokyo Nihon Steel Pipe Co., Ltd. (72 ) Inventor Tsuyoshi Sekiguchi 1-2-2 Marunouchi, Chiyoda-ku, Tokyo Nihon Steel Tube Co., Ltd. (72) Inventor Masayuki Watanabe 1-2-1 Marunouchi, Chiyoda-ku, Tokyo Nihon Steel Tube Co., Ltd.

Claims (6)

[Claims] 1. A method for burning waste plastic in a rotary kiln, comprising the following steps. (A) a step of making waste plastic particles into a fine bundle flow,
(B) A step of injecting the fine bundle flow of the waste plastic particles as fuel into the rotary kiln from above the main fuel injection position and burning it. 2. The waste plastic particles blown into the rotary kiln as a fine bundle flow are blown so that the landing range is 1/10 to 2/3 of the flame length of the main fuel. Item 1. A method for burning waste plastic in a rotary kiln according to Item 1. 3. The landing range of the waste plastic particles is
The method for burning waste plastic in a rotary kiln according to claim 1 or 2, wherein the method is in the fourth quadrant of the cross section of the rotary kiln rotating clockwise. 4. The rotary kiln according to claim 1, wherein waste plastic particles blown into the rotary kiln as a fine bundle flow are blown into contact with or cross the flame of the main fuel. Of burning waste plastics in Japan. 5. The waste plastic particles have a particle size of 20 mm.
The method for burning waste plastic in a rotary kiln according to any one of claims 1 to 4, wherein the method is the following polyethylene, polypropylene, polystyrene, or a mixture of two or more thereof. 6. The waste plastic particles have a particle size of 10 mm.
The method for burning waste plastic in a rotary kiln according to any one of claims 1 to 4, wherein the method is the following polyvinyl chloride.