JP2002254041A - Burned ash washing unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a burned ash washing unit which can miniaturize the whole facility inclusive of a washing unit and a drainage processing facility by improving the burned ash washing effect, and which can reduce cost. SOLUTION: Burned ash mixed water is sucked into a jet stream which is injected by a mixed air jet pump. By doing this, the washing water and the burned ash are collided each other violently so that the chlorine or the like in the burned ash may be dissolved into the washing water effectively.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for cleaning incinerated ash, and more particularly, to an apparatus for cleaning and removing impurities such as chlorine contained in incinerated ash generated when incinerating industrial waste.
The present invention relates to a device for cleaning incinerated ash so that it can be used as a raw material for Portland cement.

[0002]

2. Description of the Related Art As part of recycling waste and reducing waste disposal costs, the use of cinders (incinerated ash) of industrial waste as a raw material for Portland cement has been performed. In this case, impurities contained in the incineration ash, particularly chlorine content, become a serious problem as a cement raw material. Therefore, it is necessary to perform a treatment for cleaning the incineration ash to reduce the chlorine content.
Further, it is necessary to treat the washing wastewater generated by washing the incineration ash so as to satisfy the discharge standard, and then discharge the wastewater to a sewer.

[0003]

However, in the conventional incineration ash cleaning equipment, the incineration ash is simply washed by a batch process in which the incineration ash is put into water and mixed and stirred. However, there is a problem that a large amount of washing water is required and the equipment becomes large. Further, since a large amount of washing water is used, there is a problem that a wastewater treatment facility for treating washing wastewater is also increased in size. In addition, if the dewatering process of the incombustible ash having a high porosity and being incompressible is performed by a pressure type dehydrator such as a general belt press type, it is difficult to sufficiently perform the dehydration process.

[0004] Therefore, the present invention is capable of continuously and efficiently cleaning incinerated ash, reducing the amount of cleaning water used and the amount of generated cleaning wastewater, thereby improving the cleaning equipment and wastewater treatment equipment. It is an object of the present invention to provide an incineration ash cleaning apparatus capable of reducing the size and cost of the entire facility including the apparatus.

[0005]

Means for Solving the Problems In order to achieve the above object, the incineration ash cleaning apparatus of the present invention contacts incineration ash with cleaning water to elute impurities such as chlorine contained in the incineration ash into the cleaning water. An incineration ash cleaning unit comprising: an incineration ash cleaning unit; and a solid-liquid separation unit that performs solid-liquid separation of the incineration ash-containing cleaning water derived from the incineration ash cleaning unit. A hopper for mixing the washing water, and a jet pump using the washing water as a driving source, wherein the incineration ash mixed water in the hopper is formed to be sucked into a jet stream jetted from the jet pump. Features.

Further, the solid-liquid separating means includes a filter for trapping incinerated ash, and a jet pump for sucking washing water that has passed through the filter,
The washing water separated by the solid-liquid separating means is provided with a path for reusing the washing water for driving the jet pump.

Further, the incineration ash cleaning section is provided at a stage subsequent to the first cleaning section having the hopper and the jet pump,
At least one washing unit having a hopper for temporarily storing the incinerated ash-containing washing water sucked and delivered by the jet pump of the first washing unit, and a jet pump for sucking and sending the incinerated ash-containing washing water in the hopper. The washing water separated by the solid-liquid separation means is provided with a path for reusing the washing water for driving a jet pump provided in the first washing section, and a jet provided in a washing section at a subsequent stage. It is characterized by having a path for supplying fresh water for driving the pump.

[0008] Further, a path for leading overflow water from a hopper provided in the subsequent washing section, a sedimentation tank for agglomerating incineration ash floating in the overflow water led to the path with a flocculant, and separating and separating the same. A path for returning washing water containing incinerated ash precipitated and separated in the sedimentation tank to the introduction portion of the solid-liquid separation means, and a wastewater treatment facility for treating and discharging the supernatant water separated in the sedimentation tank. Features.

[0009]

FIG. 1 is a system diagram showing an embodiment of an incineration ash cleaning apparatus according to the present invention, and FIG. 2 is a sectional view showing an example of an air-mixing jet pump which is a jet pump usable in the present invention. FIG. 3 is a plan view showing an example of a dehydrator as a solid-liquid separating means, and FIG. 4 is a partial sectional front view of the same dehydrator.

The incineration ash cleaning apparatus includes a first cleaning unit 11
And an incineration ash cleaning section 10 having a second cleaning section 12, a dehydrator 20 as solid-liquid separation means, and a wastewater treatment facility 30 for purifying cleaning wastewater.

The first cleaning section 11 includes a first hopper 13 for mixing incineration ash and cleaning water, a first air-jet pump 14 driven by cleaning water, and a first air-jet pump 14. And a first driving water tank 15 for storing the driving water (washing drainage). The first washing unit 11 uses the washing drainage separated by the dehydrator 20 as the driving water also serving as the washing water. . The second cleaning unit 12 includes a second hopper 16 for temporarily storing the incineration ash-containing cleaning water from the first cleaning unit 11, a second air-mix jet pump 17 using fresh water as a driving source, and a second air-mixing jet pump. A second driving water tank 18 for storing fresh water, for example, industrial water, serving as driving water for the jet pump 17 is provided.

As shown in FIG. 2, the air-mixing jet pump operates using pressure water supplied from a pressure water pipe 41 as a drive source, and includes a pump main pipe section 43 to which a suction pipe 42 is connected, The injection pipe 44 is formed by an injection pipe 44 connected to the base end of the main pipe section 43, a nozzle 45 for jetting pressure water into the injection pipe 44 in the axial direction, and a gas inflow pipe 46 communicating with the injection pipe 44. ing.

When pressure water of a predetermined pressure is supplied from the pressure water pipe 41 and ejected from the nozzle 45, the air is sucked from the gas inlet pipe 46 by an ejector action of the ejected pressure water, and the mixed jet stream W The jet stream W is injected into the pump main pipe 43 at a high speed, so that the inside of the suction pipe 42 is in a vacuum state, and the incineration ash mixed water in the first hopper 13 or the incineration in the second hopper 16 is incinerated. The ash-containing cleaning water is sucked and pumped from the tip of the pump main pipe 43.

As described above, the air-mixing jet pump has a simple structure, has no risk of blockage in the pump and failure of the nozzle portion, eliminates cavitation, eliminates pressure limitation, and is driven by ultra-high pressure water. It is suitable not only for suction and pressure feeding of liquids such as water, but also for suction and pressure feeding of solids and solid-liquid mixtures.

By using such a mixed jet pump as a pump for sucking and pumping the incinerated ash-containing washing water as described above, incinerated ash is mixed into the mixed washing water flowing at a high speed. The washing water and the incineration ash particles collide violently, and the collision effect at the bent portion of the pipe can be obtained, so that the incineration ash can be efficiently cleaned in a short time. .

[0016] In general, a stirring and washing tank and a delivery pump are required, whereas stirring and washing and delivery can be performed simultaneously only by a mixture jet pump. Further, conventionally, the stirring washing operation and the sending operation are performed in a batch (batch) type. However, by using a mixed jet pump, the stirring washing operation and the sending operation can be performed at the same time. -Transmission can be performed continuously, and the processing efficiency can be improved.

In addition, by providing a line mixer at an appropriate position on the discharge-side pipe of the mixture jet pump, the stirring and washing action can be further enhanced. May be sucked.

In the incineration ash cleaning section 10, the incineration ash supplied from the incineration ash supply path 51 to the first hopper 13 is mixed water (washing wastewater) supplied from the first driving water tank 15 through the mixed water supply path 52. Part of) and a predetermined proportion,
The mixture is loosened by the mixing water to be in a fluid state appropriately dispersed in the water. The first mixture jet pump 14 is supplied with pressurized water from the first drive water tank 15 through the drive water supply path 53, and the incinerated ash mixed water in the first hopper 13 is supplied to the first mixture jet pump 14 from the bottom of the hopper. The air is sucked by the first air-jet pump 14 through the suction pipe portion 14a of the air jet pump 14, becomes a slurry while being vigorously stirred, passes through the first washing water path 54, and is rectified by the second hopper 16. After passing through the cylinder 16a, the flow is rectified and flows into the second hopper 16.

The incineration ash that has flowed into the second hopper 16 settles at the bottom of the second hopper 16, and the first washing wastewater separated from the incineration ash overflows the second hopper 16 and passes through the first washing wastewater discharge path. After passing through 55, it is sent to a coagulation tank 56. Pressurized water is supplied from a second driving water tank 18 through a second driving water supply path 57 to a second mixture jet pump 17 provided at the bottom of the second hopper 16. The incinerated ash mixed water accumulated in the hopper is discharged from the bottom of the hopper to the suction pipe portion 17 of the second air-jet pump 17.
a through the second aeration jet pump 17, passes through the second washing water path 58 while being vigorously stirred, and is subjected to a second washing operation (rinsing operation, rinsing operation) to be performed by the adjusting tank 5.
9 In the adjusting tank 59, the incineration ash is maintained in a state of being dispersed in the washing water by stirring by the stirring blades 60, and the incineration ash-containing washing water is supplied from the adjusting tank 59 through the dehydrator inflow path 61 to the dehydrator 20. Sent.

The dehydrator 20 includes a washing ash tank 21 into which washing water containing incineration ash flows, and a washing ash tank 21 above the washing ash tank 21.
A plurality of vacuum pads 23 which can be moved up and down by an air cylinder 22, a supernatant water tank 24 into which overflow water from the washing ash tank 21 flows, and a dewatering cake C
Formed by a conveyor 25 for transferring the vacuum pad 23, a rotating frame 26 for moving the vacuum pad 23 to the cleaning ash tank 21 and the conveyor 25, and a vacuum suction unit 27 for vacuum suction of the cleaning water from the vacuum pad 23. Have been.

The vacuum pad 23 has a filter 23b provided at an intermediate portion of a cylindrical body 23a having an open lower end, and a flexible pipe 23c connected to a vacuum suction unit 27 at an upper end of the cylindrical body. By operating the vacuum suction unit 27 with the pad 23 submerged in the cleaning ash tank 21, the incineration ash-containing cleaning water is sucked into the cylindrical body 23a, and the cleaned incineration ash (cleaning ash) is captured by the filter 23b. Then, the wastewater is separated from the washing wastewater, and the washing wastewater is sucked into the vacuum suction part 27 through the flexible pipe 23c. As a result, a dehydrated cake C made of cleaning ash from which chlorine and the like have been cleaned and removed is formed in the cylindrical body 23a.

The rotating frame 26 includes a motor 26a, a gear 26
b, it is formed so as to reciprocate in a range of 90 degrees in the horizontal direction around the shaft portion 26c. The air cylinder 22 expands and contracts by compressed air from the compressor 22a.
a, the rotating frame 26 rotates 90 degrees, and the vacuum pad 2 located in the washing ash tank 21 portion.
3 moves to the conveyor 25 and the conveyor 2
Vacuum pad 23 in 5 parts is used for cleaning ash tank 2
It is formed to move to one part.

Further, the evacuation of the vacuum pad 23 moved to the conveyor 25 is stopped, and the vacuum pad 23 is moved up and down by the air cylinder 22 as necessary, so that the dehydrated cake C is removed from the inside of the conveyor 25. It is dropped on the conveyor 25 and is conveyed from the conveyor 25 to a stock yard 29 via a dehydrated cake conveying path 28 using another conveyor or the like, and is used as a raw material of Portland cement or a landfill material.

As described above, the use of the vacuum suction type dehydrator 20 can sufficiently dehydrate incinerated ash having a high porosity and being incompressible. In particular, when the same air-mixing jet pump is used for washing and draining the vacuum in the vacuum suction unit 27 as well, the air-mixing jet pump sucks the washing wastewater by the vacuum generated by the jet flow, so that a large amount of washing wastewater is used. Even if you suck in, you can keep the vacuum of the suction part,
The dewatering effect can be further improved, and the dewatering treatment can be performed easily and reliably at low cost. This allows
The water content of the dehydrated cake can be reduced to 85% or less.

The driving water for the mixture jet pump used here includes the first driving water tank 15 and the second driving water tank 1.
The washing drainage and washing water in 8 can be used, and water from other equipment can also be used. Further, since the vacuum suction unit 27 basically sucks the cleaning wastewater containing no incineration ash, it is possible to use a normal pump.

From the vacuum pad 23 to the vacuum suction unit 27
The washing wastewater sucked in is returned to the first drive water tank 15 through the washing wastewater return path 62, and is circulated and used as pressure water for driving the first air-mixing jet pump 14. As a result, the treatment of the cleaning wastewater generated here becomes unnecessary, and the capacity of the wastewater treatment equipment 30 can be reduced.

On the other hand, the supernatant water in the supernatant water tank 24 flows into the coagulation tank 56 along with the first cleaning drainage overflowing the second hopper 16 through the second cleaning drainage channel 63. Since the washing effluent flowing into the coagulation tank 56 contains fine ash and carbon, a polymer flocculant is added to the coagulation tank 56 to form a large floc. By separating and returning the settled sludge from the settling tank 64 through the sludge return path 65 to the washing ash tank 21 of the dehydrator 20, these can be taken into the dewatered cake and used as a cement raw material.

The supernatant of the sedimentation tank 64 is sent to the wastewater treatment facility 30 through the wastewater treatment path 66 as washing wastewater containing impurities such as chlorine, and is subjected to predetermined wastewater treatment. In the wastewater treatment equipment, similar to the normal treatment procedure, for example, if necessary, pH is adjusted with sodium hydroxide or the like,
After injecting ferric chloride to form ferric hydroxide, which is the core of the agglutination reaction, injecting a heavy metal scavenger to insolubilize heavy metal ions dissolved in water, Is absorbed in ferric hydroxide or coprecipitated to remove from water.

[0029] Separation of the generated heavy metal-containing floc can be carried out by adding a polymer flocculant, if necessary, to form a coarse floc, followed by sedimentation and separation in a sedimentation tank. The precipitated floc is dehydrated by a filter press type dehydrator or the like in the same manner as before, and then discharged as a dehydrated cake having about 80% moisture. In addition, treated water
The water is discharged from the discharge path 31 to the sewer. Further, the discharged water can be returned to the second driving water tank 18 and reused by performing a chlorine reduction treatment.

As described above, the first and second cleaning units 11 and 12
By performing the washing operation twice using the air-mixing jet pump, the washing efficiency of incinerated ash can be greatly improved. Further, the amount of fresh water can be reduced by using fresh water for the second washing and circulating the washing waste water for the first washing. As a result, the discharge amount of the cleaning wastewater can be significantly reduced, so that the wastewater treatment equipment 30 installed at the subsequent stage can be downsized. Further, by performing the second washing with fresh water, it is possible to more effectively wash out chlorine content from the incinerated ash.

Further, also in the dehydrator 20, by performing the dehydration operation by vacuum suction using an air-mixing jet pump, an effective dehydration (solid-liquid separation) operation becomes possible, and the water content of the dewatered cake is reduced. be able to.

[0032]

As described above, according to the incineration ash cleaning apparatus of the present invention, it is possible to efficiently wash out chlorine and the like from the incineration ash, and the amount of cleaning water used, that is, Emissions can also be significantly reduced. Therefore, it is possible to reduce the size and cost of the entire equipment including the cleaning equipment for cleaning incinerated ash and the wastewater treatment equipment for purifying the cleaning wastewater discharged from the cleaning equipment.

[Brief description of the drawings]

FIG. 1 is a system diagram showing one embodiment of an incineration ash cleaning device of the present invention.

FIG. 2 is a cross-sectional view illustrating an example of an air-fuel mixture jet pump.

FIG. 3 is a plan view showing an example of a dehydrator serving as a solid-liquid separation unit.

FIG. 4 is a partially sectional front view of the dehydrator.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 ... Incineration ash washing | cleaning part, 11 ... 1st washing | cleaning part, 12 ... 2nd washing | cleaning part, 13 ... 1st hopper, 14 ... 1st air-mixing jet pump, 15 ... 1st drive water tank, 16 ... 2nd hopper, 16
a: rectifying cylinder, 17: second mixture jet pump, 18: second drive water tank, 20: dehydrator, 21: washing ash tank, 22
... air cylinder, 23 ... vacuum pad, 24 ... supernatant water tank, 25 ... conveyor, 26 ... rotating frame, 27 ... vacuum suction part, 28 ... dewatering cake transport path, 29 ... stock yard, 30 ... wastewater treatment equipment, 31 ... Discharge path, 41: pressure water pipe, 42: suction pipe, 43: pump main pipe section, 44: injection pipe, 45: nozzle, 46: gas inflow pipe, 51: incineration ash supply path, 52: mixed water supply path, 53 .., Driving water supply path, 54, first cleaning water path, 55, first cleaning drainage extraction path, 56, flocculation tank, 57, second driving water supply path, 58,
Second washing water path 59 adjustment tank 60 stirring blade 61 61
Dewatering machine inflow path, 62 ... washing drainage return path, 63 ... second
Cleaning drainage route, 64: sedimentation tank, 65: sludge return route, C
... dehydrated cake, W ... jet flow

Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat II (Reference) C02F 1/56 B01D 29/04 530D B09B 3/00 ZAB 304G (71) Applicant 592075884 Kiyomoto Iron Works Co., Ltd. Nobeoka, Miyazaki 6133-16 Todororo-cho, Tokyo (72) Inventor Yoshito Yamanishi 1-3-3 Kyobashi, Chuo-ku, Tokyo Inside Maezawa Kogyo Co., Ltd. (72) Inventor Iwan Takayama 2-1-1-1, Uchikanda, Chiyoda-ku, Tokyo Orie 3B201 AA46 AA48 AB01 BB21 BB77 BB87 BB88 BB90 BB92 CC12 CD22 4D004 AA36 AB06 BA02 CA34 CA40 CB05 4D015 BA09 BB05 DB01 EA06 EA32 FA19 FA22

Claims (6)

[Claims] 1. An incineration ash cleaning section for bringing incineration ash into contact with cleaning water to elute impurities such as chlorine contained in the incineration ash into the cleaning water, and an incineration ash-containing cleaning water derived from the incineration ash cleaning section. In the incineration ash cleaning device provided with solid-liquid separation means for performing solid-liquid separation, the incineration ash cleaning unit has a hopper for mixing incineration ash and cleaning water, and a jet pump using the cleaning water as a driving source. An incineration ash cleaning device characterized in that the incineration ash mixed water in the hopper is sucked into a jet stream jetted from the jet pump. 2. The incinerated ash according to claim 1, wherein said solid-liquid separating means includes a filter for trapping the incinerated ash, and a jet pump for sucking the washing water passed through the filter. Cleaning equipment. 3. The washing water separated by the solid-liquid separation means,
The incineration ash cleaning apparatus according to claim 1, further comprising a path that is reused for driving the jet pump. 4. The incineration ash cleaning section includes a first cleaning section provided with the hopper and the jet pump.
At least one washing unit having a hopper for temporarily storing the incinerated ash-containing washing water sucked and delivered by the jet pump of the washing unit, and a jet pump for sucking and sending the incinerated ash-containing washing water in the hopper. The apparatus for cleaning incinerated ash according to claim 1, characterized in that: 5. The washing water separated by the solid-liquid separation means,
It is provided with a path for reuse of a jet pump provided in the first washing section and a path for supplying fresh water for driving a jet pump provided in a subsequent washing section. The incineration ash cleaning device according to claim 4. 6. A path for leading overflow water from a hopper provided in the subsequent washing section, a sedimentation tank for agglomerating incineration ash floating in the overflow water led to the path with a flocculant to separate and separate the incinerated ash. A path for returning washing water containing incinerated ash precipitated and separated in the sedimentation tank to the introduction portion of the solid-liquid separation means, and a wastewater treatment facility for treating and discharging the supernatant water separated in the sedimentation tank. The incineration ash cleaning device according to claim 4, characterized in that: