Not Applicable
1. Technical Field of the Invention
The present invention relates to a cement burning apparatus capable of safely and efficiently drying high-water-content organic waste such as high-water-content organic sludge and a method of drying high-water-content organic waste utilizing the apparatus.
2. Description of the Related Art
Conventionally, variety of apparatus and methods for treating waste such as city garbage in cement burning apparatus has been proposed. For instance, in the first patent document is disclosed a technology, in which a part of hot air from a clinker cooler is introduced to a dryer for drying waste such as city garbage; gas exhausted from the dryer is returned to the clinker cooler; and the hot air, with which the exhaust gas is mixed, from the clinker cooler is used as air for combustion in a cement kiln or a calciner.
Further, in the second patent document, a technology for burning combustible waste in cement burning apparatus is disclosed. In this technology, combustible waste is burned with a part of hot air from a clinker cooler; exhaust gas generated in a waste burning process is aerated to a preheater for heating cement raw material; and slug generated in the waste burning process is extracted.
Patent document 1: Japanese Patent Publication Showa 63-151650 gazette
Patent document 2: Japanese Patent Publication 2003-506299 gazette
However, as described in the above patent documents, the hot air extracted from the clinker cooler can be utilized for drying waste such as city garbage, combustible waste and the like without causing any trouble, but when the hot air is utilized for drying high-water-content organic waste such as high-water-content-organic sludge, oxygen concentration of the hot air is high so that there is a danger of explosion.
In addition, even if combustion exhaust gas downstream from the exit of a preheater of a cement burning apparatus was tried to be utilized, since temperature of the combustion exhaust gas in the range was low, that is, 450° or less, the gas would not be suitable to dry the high-water-content sludge.
Further, gas extracted from the inlet end of a cement kiln is low in oxygen concentration and high in temperature, that is, approximately 1000°, so that it is suitable to dry the high-water-content organic waste, but extraction of the combustion gas from the inlet end causes a problem that thermal efficiency of the cement kiln decreases.
In addition, since dry exhaust gas that is generated after organic sludge and the like are dried includes a great deal of odorous component, it is necessary to discharge it after deodorization treatment. In order to perform the deodorization treatment, temperature of the gas including odorous component is preferably adjusted to 800° or more and the deodorization treatment is generally performed by introducing the gas to a combustion range such as a calciner. But, when gas exhausted from a cement kiln is utilized for drying the organic sludge and the like, and dry exhaust gas is treated in the above range, since the oxygen concentration of the dry exhaust gas is low, combustion state is degenerated and thermal efficiency of the cement kiln decreases, therefore, the gas exhausted from a cement kiln is not suitable to dry organic sludge and the like.
In addition to the above, the high-water-content organic sludge shapes clumps including 40 mass percent of water or more like clay and its specific surface area is small, which makes it difficult to efficiently dry the organic sludge.
The present invention has been made in consideration of the above problems in the conventional art, and the object thereof is to provide a cement burning apparatus and a method of drying high-water-content organic waste precluding the possibility of explosion of the dryer and the like; not causing decreased thermal efficiency of a cement kiln; and more efficiently drying high-water-content organic waste.
To achieve the above object, the present invention relates to a cement burning apparatus, and the apparatus is characterized by comprising: a dryer, to which combustion gas is fed from an exhaust gas passage, which runs from an outlet duct of a calciner to an outlet duct of a cyclone immediately below a highest cyclone of a preheater of a cement kiln, for drying high-water-content organic waste of which water content is 40 mass percent or more by using the combustion gas.
Oxygen concentration of the combustion gas extracted from the exhaust gas passage, which runs from the outlet duct of the calciner to the outlet duct of the cyclone immediately below the highest cyclone of the preheater of the cement kiln is low, that is, 2 to 8 percent, so that there is no danger of explosion of the dryer, and since temperature of the combustion gas is 450 to 900°, the high-water-content organic waste can sufficiently be dried. In addition, combustion gas is not extracted from an inlet end or the like of the cement kiln, so that thermal efficiency of the cement kiln is not decreased.
In the above cement burning apparatus, the dryer can be a grinding-type flash dryer, to which the combustion gas is fed so as to directly be contacted with the high-water-content organic waste, for drying the organic waste while grinding it. With this, improved drying efficiency through increased specific surface area of the high-water-content organic waste and improved grinding efficient through superficial drying of the high-water-content organic waste can between them exponentially improve overall drying efficiency.
In the above cement burning apparatus, it is possible to mount a second exhaust gas passage for returning exhaust gas from the dryer to the exhaust gas passage, which runs from the outlet duct of the calciner to the outlet duct of the cyclone immediately below the highest cyclone of the preheater of the cement kiln. With this second exhaust gas passage, it becomes unnecessary to introduce dry exhaust gas with low oxygen concentration and odorous component to a combustion range such as a calciner and perform deodorization treatment, so that thermal efficiency of the cement kiln is not degenerated.
In the above cement burning apparatus, the high-water-content organic waste may be high-water-content organic sludge, and paper sludge, sewerage sludge, building pit sewerage sludge, food sludge and so on may be dried.
Further, the present invention relates to a method of drying high-water-content organic waste, and the method is characterized by comprising the steps of: extracting a part of combustion gas from an exhaust gas passage, which runs from an outlet duct of a calciner to an outlet duct of a cyclone immediately below a highest cyclone of a preheater of a cement kiln; and drying high-water-content organic waste of which water content is 40 mass percent or more by utilizing the part of the extracted gas. With this method, as described above, there is no danger of explosion; thermal efficiency of the cement kiln does not degenerate, and the high-water-content organic waste can safely and efficiently be dried.
In the above method of drying high-water-content organic waste, the part of the combustion gas may directly be contacted with the high-water-content organic waste, and the organic waste can be dried while being ground. With this, as described above, overall drying efficiency can exponentially be improved.
The above method of drying high-water-content organic waste may further comprise a step of returning gas after drying the high-water-content organic waste to an exhaust gas passage, which runs from the outlet duct of the calciner to the outlet duct of the cyclone immediately below the highest cyclone of the preheater of the cement kiln. With this method, as described above, the dry exhaust gas including the odorous component can be treated without degenerating thermal efficiency of the cement kiln.
In the above method of drying high-water-content organic waste, the high-water-content organic waste may be high-water-content organic sludge such as paper sludge, sewerage sludge, building pit sewerage sludge and food sludge.
As described above, with the present invention, it is possible to provide a cement burning apparatus and a method of drying high-water-content organic waste, which can preclude the possibility of explosion; prevent decreased thermal efficiency of the cement kiln; and more efficiently dry high-water-content organic waste.
The cement kiln 2, the preheater 3 and the calciner 4 have the same construction as conventional cement burning apparatus, and cement raw material R fed to the preheater 3 is preheated in the preheater 3; calcined in the calciner 4; and burned in the cement kiln 2.
To the dryer 6 is fed high-water-content organic waste (hereinafter referred to as “waste”) W such as high-water-content organic sludge, and to the dryer 6 is fed combustion gas extracted from an exhaust gas passage running from the lowest cyclone 3A to the second cyclone 3B to dry the waste W. The combustion gas is low in oxygen concentration, that is, approximately 2 to 8 percent, so that there is no danger of explosion of the dryer 6. In addition, temperature of the combustion gas is approximately 800 to 900°, which allows the high-water-content organic waste to sufficiently be dried. The dried waste W may be treated in and out of the cement burning apparatus 1.
The fan 7 is installed to introduce combustion gas from the preheater 3 to the dryer 6 and exhaust gas from the fan 7 is returned to the exhaust gas passage, which runs from the lowest cyclone 3A to the second cyclone 3B via a circulation duct 8. With this, odorous component included in dry exhaust gas generated after drying organic sludge and the like is subject to a deodorization treatment.
Meanwhile, although in the embodiment described above, the gas extracted from the exhaust gas passage, which runs from the lowest cyclone 3A to the second cyclone 3B, is fed to the dryer 6, combustion gases extracted from exhaust gas passages upstream from the second cyclone 3B of the preheater 3, which run from the second cyclone 3B to the third cyclone 3C (temperature of the combustion gas is approximately 700 to 800°) and from the third cyclone 3C to the forth cyclone 3D (temperature of the combustion gas is approximately 550 to 650°) can be fed to the dryer 6. Further, the area, to which dry exhaust gas from the dryer 6 is returned, is not limited to the exhaust gas passage, which runs from the lowest cyclone 3A to the second cyclone 3B, and the dry exhaust gas can be returned to the same area as in the case that the combustion gas described above is extracted.
The cement-raw-material recovery cyclone 16 is installed upstream from the grinding-type flash dryer 17 to remove dust included in combustion gas G extracted from the exhaust passage of the preheater 3 and to feed the combustion gas G of which dust is removed to the grinding-type flash dryer 17.
The grinding-type flash dryer 17 is installed to dry high-water-content organic waste (hereinafter referred to as “waste” according to circumstances) W such as high-water-content organic sludge fed from the waste storage tank 18 with the combustion gas G fed from the cement-raw-material recovery cyclone 16 while grinding the waste W. This grinding-type flash dryer 17 is provided with a feed opening for the waste W in the upper portion thereof and a feed opening for the combustion gas G from the cement-raw-material recovery cyclone 16 in the lower portion thereof, and the waste W and the combustion gas G are counter-currently contacted with each other. Further, in the grinding-type flash dryer 17 are installed a rotation shaft 17a and strike chains 17b, which are fixed to the rotation shaft 17a and horizontally extend and rotate through centrifugal force together with the rotation of the rotation shaft 17a to grind the waste W.
The waste storage tank 18 is installed to temporarily store the high-water-content organic waste and the high-water-content organic waste can be high-water-content organic sludge such as paper sludge, sewerage sludge, building pit sewerage sludge and food sludge.
A blower 19 is installed to transport the waste W ground and dried by the grinding-type flash dryer 17 to the preheater 13, and a roots blower or the like is utilized. A fan 22 is installed to return dry exhaust gas G′ discharged from the grinding-type flash dryer 17 via a circulation duct 20 to the preheater 13.
Next, the motion of the cement burning apparatus 11 with the above construction will be explained with reference to figures.
Cement raw material R is fed to the preheater 13 of the cement burning apparatus 11, and the raw material R is preheated in the preheater 13; calcined in the calciner 14; and burned in the cement kiln 12. On the other hand, received waste W is temporarily stored in the waste storage tank 18.
The fan 22 is operated to introduce the combustion gas G of the cement kiln 12 to the cement-raw-material recovery cyclone 16, and dust included in the combustion gas G is recovered. The recovered dust is returned to the preheater 13, and the combustion gas G from which the dust is recovered is fed to the grinding-type flash dryer 17.
The waste W from the waste storage tank 18 is fed to the upper portion of the grinding-type flash dryer 17, and the combustion gas G from the cement-raw-material recovery cyclone 16 is introduced to the lower portion of the grinding-type flash dryer 17. Since temperature of this combustion gas G is approximately 800 to 900°, high-water-content organic waste can sufficiently be dried. In addition, in the grinding-type flash dryer 17, the waste W and the combustion gas G is directly and counter-currently contacted with each other, and the waste W is dried while being ground by strike chains 17b arranged in the grinding-type flash dryer 17, the waste W is dried from its surface with specific surface area thereof increasing. As a result, in addition to improved drying efficiency due to the increase of the specific surface area, grinding efficiency is also improved due to the dried surface of the waste W, resulting in exponential improvement in overall drying efficiency in comparison to conventional devices. Besides, oxygen concentration of the combustion gas G introduced in the grinding-type flash dryer 17 is low, that is, approximately 2 to 8 percent, so that there is no danger of explosion of the grinding-type flash dryer 17 and others.
Here, in case that outlet gas temperature of the grinding-type flash dryer 17 is too high, which may caused by temporary decrease of the quantity of the waste W to the grinding-type flash dryer 17, cooling air C can be introduced upstream from the grinding-type flash dryer 17.
Next, with the dried-material recovery cyclone 21, the ground and dried waste W by the grinding-type flash dryer 17 is recovered, and is returned to the preheater 13 by operating the blower 19. In addition, the recovered waste W can be transported by the blower 19 to apparatus other than the cement burning apparatus 11, and the waste W can be treated by the apparatus.
On the other hand, the dry exhaust gas G′ discharged from the grinding-type flash dryer 17 is returned to an exhaust gas passage, which runs from the lowest cyclone 13A to the second cyclone 13B, through the circulation duct 20 by the fan 22. With this, odorous component included in the dry exhaust gas G′ generated after organic sludge and the like is dried can be subject to deodorization treatment.
Meanwhile, although in the embodiment example described above, the combustion gas G extracted from the exhaust gas passage, which runs from the lowest cyclone 13A to the second cyclone 13B, is fed to the grinding-type flash dryer 17, combustion gases extracted from exhaust gas passages upstream from the second cyclone 13B of the preheater 13, which run from the second cyclone 13B to the third cyclone 13C (temperature of the combustion gas is approximately 700 to 800°) and from the third cyclone 13C to the forth cyclone 13D (temperature of the combustion gas is approximately 550 to 650°) can be fed to the grinding-type flash dryer 17.
Further, as to the dry exhaust gas G′ also, it is not limited that the gas G′ is returned to the exhaust gas passage, which runs from the lowest cyclone 3A to the second cyclone 3B, but the gas G′ can be returned to the same area as in the case that the combustion gas G described above is extracted.
Number | Date | Country | Kind |
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2006-177618 | Jun 2006 | JP | national |
2007-034206 | Feb 2007 | JP | national |
The present application claims priority to International Application No. PCT/JP2007/062751 which was filed on Jun. 26, 2007 and claims priority to Japanese Patent Application No. 2006-177618 filed on Jun. 28, 2006 and Japanese Patent Application No. 2007-034206 filed on Feb. 15, 2007.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/062751 | 6/26/2007 | WO | 00 | 9/1/2009 |