JP3156297U - Waste melting treatment plant - Google Patents

Abstract

Disclosed is an emission melting treatment plant that contributes to detoxifying various gases generated in an oil conversion treatment. SOLUTION: Molten oil for melting discharge 11 is stored, inner pot 21 having a processing space into which discharge 11 can be charged, and molten oil stored in inner pot 21 by heating inner pot 21 A melting device 20 having an outer pot 25 for maintaining the temperature of the reactor at a predetermined temperature, a desalting device 30 for removing the chlorine-based gas discharged from the melting device 20, and an exhaust gas from which the chlorine-based gas has been removed A cooling device 40 for cooling, an oil / water recovery device 50 for removing moisture and oil from the cooled exhaust gas, a gas combustion furnace 60 for burning unrecovered gas that has not been recovered by the oil / water recovery device 50, Is provided. The gas combustion furnace 60 includes a combustion auxiliary body heated to a higher temperature than the unrecovered gas in order to completely burn the unrecovered gas. [Selection] Figure 1

Description

  The present invention is a technology relating to a plant capable of melting and oiling wastes that can be oiled and wastes (for example, waste plastic, polystyrene foam, etc.).

Conventionally, processing of plastics, polystyrene foam and the like has been performed by incineration or landfill. In the case of incineration, since many of the objects to be treated are made of plastic, there are problems such as shortening the life of the incinerator and preventing dioxin generation.
In addition, in the case of drug processing, the handling is dangerous and it cannot be easily processed. For this reason, in order to solve the above-mentioned problem, ingenuity for improving combustion technology is often made.

In order to prevent the generation of dioxins, treatment by complete combustion is preferable. Therefore, when searching the patent literature using the keyword “plant × complete combustion”, 38 hits were found. Among them, a technique as described in Patent Document 1 was extracted.
According to this technique, the decomposition and complete combustion of the dioxin precursor are performed, and incomplete combustion at the time of incineration low temperature combustion accompanying intermittent operation is suppressed by the iron compound catalyst.

Japanese Patent Laid-Open No. 11-267507

However, as described in the patent specification, the above technique is “a technique for completely burning garbage in an intermittent operation incinerator such as a mechanized batch furnace or a quasi-continuous furnace”.
On the other hand, since the inventor presupposes an oil conversion process, searching for patent documents using the keyword “oil conversion × plant × complete combustion” did not find any hits.
In addition, a search was also made for an oil component carbonization apparatus such as waste rubber, and Japanese Patent Application Laid-Open No. 2000-290661 was examined, but a technique related to the present invention was not found.

The problem to be solved by the present invention is to provide a technique that contributes to detoxifying various gases generated in the oily treatment.
The object of the invention described in claims 1 to 5 is to provide an exhaust melting treatment plant that contributes to detoxifying various gases generated in the oil conversion treatment.

The present invention relates to a processing plant for melting a predetermined discharge (11) that can be converted to oil.
That is, the molten oil for melting the discharge (11) is stored and the inner pot (21) provided with a treatment space into which the discharge (11) can be charged and the inner pot (21) are heated to A melting device (20) having an outer pot (25) for maintaining the temperature of the molten oil stored in the inner pot (21) at a predetermined temperature, and chlorine gas discharged from the melting apparatus (20) are removed. A demineralizer (30) for cooling, a cooling device (40) for cooling the exhaust gas from which chlorine gas has been removed by the demineralizer (30), and an exhaust gas cooled by the cooling device (40) An oil / water recovery device (50) for removing moisture and oil from the gas, and a gas combustion furnace (60) for burning unrecovered gas that has not been recovered by the oil / water recovery device (50).
The gas combustion furnace (60) includes a combustion auxiliary body heated to a higher temperature than the unrecovered gas in order to completely burn the unrecovered gas, in an exhaust melting treatment plant characterized by is there.

(Glossary)
The “combustion auxiliary body” is an auxiliary material for complete combustion in order to make unrecovered gas harmless. In order to increase the area in contact with the unrecovered gas, for example, a plate or a cylinder having a mesh structure is used. The material is, for example, stainless steel that can be heated to a temperature higher than that of the unrecovered gas (for example, 900 degrees Celsius or more and 1200 degrees Celsius or less).

(Function)
The above-described device performs the following operations.
First, the molten oil in the inner pot (21) is heated by heating from the outer pot (25). Then, the discharged material is put into the inner pot (21). Then, the discharged material is melted by the melting device (20) and oiling is started, so that the oiled oil is recovered in the inner pot (21).
The desalination device (30) removes the chlorine-based gas discharged from the melting device (20), and the cooling device (40) cools the exhaust gas from which the chlorine-based gas has been removed by the desalination device (30). Then, the oil / water recovery device (50) removes moisture and oil from the cooled exhaust gas.
The unrecovered gas that has not been recovered by the oil / water recovery device (50) is completely removed in the gas combustion furnace (60) via a combustion auxiliary body heated to a temperature higher than the combustion temperature of the unrecovered gas. Burned and rendered harmless.

The above-described device can also provide the following variations.
That is, the inner hook (21) includes a raised bottom portion (21a) that rises from the bottom toward the top, and the outer hook (25) has a recess for forming the raised bottom (21a). A raised bottom heating unit for applying thermal energy is provided.
The raised bottom portion (21a) is characterized in that it is positioned so as to go through an internal space that is far from the side surface of the inner hook (21).

(Function)
When the raised bottom heating part of the outer pot (25) heats the raised bottom part (21a) of the inner pot (21), the raised bottom part (21a) is positioned so as to pass through the inner space far from the side surface of the inner pot (21). Therefore, the inner space of the inner pot (21) is heated evenly, which contributes to suppressing a partial temperature drop of the molten oil.

The above-described device can also provide the following variations.
That is, the inner pot (21) is provided with a solid separation filter (26) having a spider web shape for separating a residue precipitated on the bottom surface and a solid material to be separated from the residue. Features.

(Function)
The solid separation filter (26) in the form of a spider web is provided in the inner pot (21), so that solids such as metals that have not been oiled can be converted into oil by the solid separation filter (26). Can be separated from the oil. Without this solid matter separation filter (26), oil with high viscosity adhered to the solid matter, and it took time and effort to remove it.

The above-described device can also provide the following variations.
That is, the inner hook (21) includes an inner lid (21b) that can move from the upper side to the lower side along the inner surface forming the inner space, and an inner lid for moving the inner lid (21b) up and down. And a vertical movement mechanism (21c).

  The “inner lid vertical movement mechanism (21c)” is a mechanism that can move the inner lid (21b) up and down as needed. For example, there are a link mechanism, a rack and pinion, a chain type, and the like.

(Function)
Since the discharge contains a lot of air, it floats against the molten oil. For this reason, there is a case in which the melting of the discharge does not proceed and a large amount of the discharge cannot be input. Therefore, the discharged waste discharged is pushed down by the inner lid (21b) and the inner lid vertical movement mechanism (21c) for moving the inner lid (21b) up and down to promote melting of the discharged matter. As a result, it becomes possible to input a large amount of waste quickly.

The above-described device can also provide the following variations.
In other words, the combustion auxiliary body (65) is built in by being heated to 900 degrees Celsius or more and 1200 degrees Celsius or less.

(Function)
A combustion auxiliary body (65) is built in the gas combustion furnace (60). The unrecovered gas whose temperature has been rapidly increased by the combustion auxiliary body (65) burns without incomplete combustion. The combustion temperature is preferably closer to 1200 degrees, but if it is higher, the burden on other equipment in the plant increases. The reason why the temperature is 900 degrees Celsius or higher is that complete combustion is difficult below this temperature.

The above-described device can also provide the following variations.
That is, between the inner pot (21) and the outer pot (25) in the melting device (20), an exhaust gap (29) for exhausting combustion gas from the outer pot (25), and its exhaust A chimney (28) communicating from the gap (29) to the outside of the outer hook (25) is provided. A partition flange (27) for vertically dividing the exhaust gap (29) is provided directly below the chimney (28), and the partition flange (27) is provided with a through-hole that allows the upper and lower sides of the exhaust gap (29) to communicate with each other. 27a), and the through hole (27a) is formed so that the amount of communication is larger at a position far from the chimney (28) than at a position near the chimney (28).
As a means for forming the through hole (27a) so that the communication amount is larger at a position far from the chimney (28) than at a position near the chimney (28), for example, the through hole (27a) at a position far from the chimney (28) Increase size and density.

(Function)
Some conventional melting apparatuses (20) include an inner pot (21) and an outer pot (25), but the exhaust gap (29) is uniform. That is, the inner hook (21) is positioned at the center inside the outer hook (25). The chimney (28) has a role of letting the combustion gas to be exhausted out of the outer pot (25), but the location is one place due to the role of the chimney (28). It was found that if the chimney (28) was provided only at one location and the exhaust gap (29) was uniform, incomplete combustion was likely to occur at a position far from the chimney (28).
Therefore, with the configuration as described in claim 6, incomplete combustion corresponding to the distance from the chimney (28) in the inner hook (21) is reduced. In the conventional configuration, the amount of ventilation increases as the exhaust gap (29) close to the chimney (28). In the configuration described in claim 6, it is considered that the amount of ventilation in the exhaust gap (29) is equalized. .

The above-described device can also provide the following variations.
That is, the desalting apparatus (30) is a cylindrical desalting unit (31) for detoxifying chlorinated gas, and a funnel-shaped wax recovery unit that is continuous to the lower part of the desalting unit (31). Part (32), wherein the desalting part (31) is 400 degrees Celsius or more.

The “demineralization device (30)” is a device that renders harmless by reacting chlorinated gas with slaked lime from the gas generated from the melting device (20).
The gas generated from the melting device (20) contains vaporized oil, which is cooled by the cooling device (40) and recovered by the oil / water recovery device (50). The recovered oil includes wax oil in addition to heavy oils. However, it has been found that wax oil may be separated in the desalting step in the desalting apparatus. Therefore, by adopting the configuration as described in claim 7, the wax oil can be actively collected in the desalting step.
In order to set the desalting unit (31) to 400 degrees Celsius or more, for example, the exhaust heat of the melting device (20) is used through a chimney.

(Function)
In the desalting section (31), chlorine gas is made harmless by chemical reaction at 400 degrees Celsius or higher from the gas generated from the melting device (20). The wax recovery part (32) located below the desalting part (31) has a temperature that is partially or entirely lower than that of the above chemical reaction, and is, for example, a place of 240 degrees Celsius or less. Therefore, the wax oil can be collected in the funnel collecting unit (32) having a funnel shape.

  ADVANTAGE OF THE INVENTION According to this invention, the melt processing plant of the discharge which contributes to detoxifying various gas generated in an oil-ized process was able to be provided.

It is a schematic block diagram of the plant concerning this embodiment. It is sectional drawing which shows one of the principal parts in this plant. It is a top view which shows one of the principal parts in this plant. It is sectional drawing which shows the excess gas combustion furnace in this plant. It is a top view which shows the excess gas combustion furnace in this plant. It is a top view which shows the combustion auxiliary body incorporated in the excess gas combustion furnace. It is detail drawing of a desalination apparatus. It is a figure which shows the relationship between the inner pot and the outer pot in a melting apparatus.

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 8.
In FIG. 1, the process procedure in the plant which concerns on this embodiment is shown with the block diagram.
Using a transportation means such as a forklift, the discharge 11 is put into the inner pot 21 in the melting apparatus 20 from the storage place 10. In the inner pot 21, molten oil for melting the discharge 11 is stored in advance.
The discharge 11 is a discharge or waste that can be liquefied, such as general waste plastic, waste polystyrene foam, and FRP. In the present embodiment, a medical effluent discharged at a medical site is selected as the effluent 11, and points unique to the effluent 11 will be described as necessary.

The “molten oil” is an oil having a specific gravity lighter than that of the liquid phase of the discharged product and having a flash point and a flash point higher than the melting point of the plastic. In this embodiment, soybean oil is used. Incidentally, olive oil, which is a non-drying vegetable oil similar to soybean oil, has a specific gravity of 0.91, a flash point of 225 ° C., and an ignition point of 343 ° C. On the other hand, the melting point of polystyrene, which is one of the treatment targets, is 160 to 180 ° C. and the specific gravity is 1.0 to 1.3, all satisfying the above requirements.
In this embodiment, about 3000 liters are stored in the inner pot 21 as molten oil.

As shown in FIG. 2, the inner pot 21 into which the discharge 11 has been put is heated by being put in the outer pot 25 with the lid 22 fixed.
The inner hook 21 includes a raised bottom portion 21a that rises from the bottom portion toward the upper portion. Further, the outer hook 25 is provided with a raised bottom heating portion (not shown) for applying thermal energy to the concave portion for forming the raised bottom portion 21a.
The raised bottom portion 21a is positioned so as to pass through an internal space that is far from the side surface of the inner hook 21. For this reason, the internal space of the inner pot 21 is heated evenly, which contributes to suppressing a partial temperature drop of the molten oil.

As melting of the discharge 11 proceeds, metal that is not oiled falls to the bottom of the inner pot 21. As shown in FIG. 3, a solids separation filter 26 having a spider web shape is provided in the lower part of the inner space of the inner pot 21. Therefore, it is possible to separate the residue that precipitates on the bottom surface and the solid material that should be separated from the residue.
The impurities that have fallen under the solids separation filter 26 are later crushed by a primary crusher, and then sorted into carbon and metal by a crushing and sorting machine 70 and used as a recycling resource.

  As the oil conversion process proceeds, gas is generated from the lid portion 22 of the inner pot 21. First, chlorine is separated from the gas by the desalination apparatus 30 and used as a chlorinated compound in a soil improvement material or the like.

The exhaust gas from which the chlorine-based gas has been removed by passing through the desalting apparatus 30 is cooled by the cooling apparatus 40.
The cooling device 40 cools the primary cooler 43, the secondary cooler 44 that further cools the exhaust gas cooled by the primary cooler 43, and the primary cooler 43 and the secondary cooler 44. A pump 42 for circulating water and a cooling water tank 41 for storing the cooling water are provided.

  Water and oil are removed from the exhaust gas cooled by the cooling device 40 by the oil / water recovery device 50. The oil / water recovery device 50 removes fine solids and the like from the oil / water recovery tank 51 that stores a liquid in which oil and water liquefied by cooling are mixed, and the oil and water recovered in the oil / water recovery tank 51. A filter 52, an oil / water separation tank 53 for storing the liquid filtered by the filter 52, an oil / water separator 55 for separating oil from the liquid stored in the oil / water separation tank 53, and an oil / water separation tank for the oil / water separator 55 A pump 54 for feeding 53 liquids and an oil production and fuel tank 56 for producing oil are provided.

The unrecovered gas that has not been liquefied by the cooling device 40 is burned in the excess gas combustion furnace 60 after passing through the safety device 61.
As shown in FIG. 6, a combustion auxiliary body 65, which is a mesh plate made of stainless steel, is heated to 900 ° C. or more and 1200 ° C. or less inside the excess gas combustion furnace 60. Although it is desirable that it is close to 1200 degrees, if it is more, the burden on other equipment of the plant increases. The reason why the temperature is set to 900 degrees Celsius or higher is that the burner temperature is about 900 degrees Celsius.
The unrecovered gas whose temperature has been rapidly increased by the combustion auxiliary body 65 burns without incomplete combustion.
It has been confirmed that the excess gas combustion furnace 60 does not cause incomplete combustion even with excess gas generated when processing about 1500 kilograms of exhaust.

When the combustion is finished, it is cooled by the cooling water tank 62 and the processing in this plant is finished.
The oil stored in the oil production and fuel tank 56 is refined and separated for each application. For example, if it is separated and recovered as heavy oil, it can be used as fuel in the outer pot 25.

Now, in order to streamline the process of charging the discharge 11 from the storage place 10 to the inner pot 21 in the melting apparatus 20, the inner pot 21 can be mounted on a truck and transported.
If the oil for oil treatment is heated and put in the inner pot 21 and transported while keeping warm, pretreatment of the oil treatment can be performed and air contained in the discharge 11 can be removed. Volume reduction is possible and transportation can be streamlined.

Based on FIG. 7, the desalting apparatus 30 is demonstrated.
In this desalinator, two desalting tanks are connected by a processing gas discharge pipe 34, and the desalting process is performed twice on the dry distillation gas generated from the melting apparatus 20 to be completely close. The desalting is performed and the cooling device 40 is sent.
Each desalting tank includes a cylindrical desalting unit 31 that is slightly expanded upward, and a funnel-shaped wax recovery unit 32 that is continuous with the lower part of the desalting unit 31.

  Desalination is performed with slaked lime. Although not shown in the drawings, the desalting unit 31 is provided with a large number of slaked lime in a shelf shape, and is provided with a net for filtering solid matter at the boundary with the wax recovery unit 32. A ceramic ball is disposed on the net. In order to keep the dry distillation gas generated from the melting apparatus 20 at 400 degrees Celsius or more (500 degrees Celsius or less), waste heat from the melting apparatus 20 is also used.

The dry distillation gas is maintained at 240 degrees Celsius or higher even in the lower part of the desalting unit 31, but wax oil with a large amount of impurities starts to accumulate in the wax recovery unit 32. The wax oil from which the solid matter has been removed by the net is recovered by the wax recovery unit 32.
Since the recovered wax is solidified at 30 degrees Celsius or less, the wax is taken out from the wax collection unit 32 through a valve before solidifying.

  FIG. 8 shows the relationship between the inner hook 21 and the outer hook 25 in the melting device 20. Between the inner pot 21 and the outer pot 25 in the melting device 20, there are an exhaust gap 29 for exhausting combustion gas from the outer pot 25, and a chimney 28 communicating from the exhaust gap 29 to the outside of the outer pot 25. Is provided. Further, a partition flange 27 is provided immediately below the chimney 28 to partition the exhaust gap 29 vertically.

  In the partition flange 27 shown in FIG. 8 (B), through holes 27a that allow the upper and lower sides of the exhaust gap 29 to communicate with each other are evenly positioned. On the other hand, the partition flange 27 shown in FIG. 8 (D) increases the density of the through holes 27a located far from the chimney 28. As a result, the communication amount of the exhaust gap 29 at a position far from the chimney 28 is larger than that at a close position. For this reason, in the configuration shown in FIGS. 8C and 8D, the degree of combustion with respect to the inner hook 21 is made uniform, and incomplete combustion is reduced, compared with the configuration shown in FIGS. 8A and 8B. be able to.

In addition, although illustration is abbreviate | omitted, as the relationship between the inner hook 21 and the outer hook 25 in the melting apparatus 20 for reducing the incomplete combustion in the inner hook 21, it can also comprise as follows.
That is, the position of the inner hook 21 with respect to the outer hook 25 is determined such that the exhaust gap 29 at a position far from the chimney 28 is larger than the exhaust gap 29 at a position near the chimney 28. In this way, the exhaust gap 29 at a position far from the chimney 28 has a larger communication amount than a close position, and incomplete combustion in the inner hook 21 can be reduced.

Further, although not increasing the density of the through holes 27a far from the chimney 28, the through holes 27a having a uniform size are arranged at equal intervals, and although not shown, a shutter is provided in each through hole 27a. Then, the size of the substantial through hole 27a is adjusted by slightly closing the shutter, or the density of the substantial through hole 27a is adjusted by providing several through holes 27a that completely close the shutter. This can also be realized.

  The present invention can be used in the transport industry of waste that can be oiled, the recycling industry such as oil processing, the medical waste processing industry, and the like.

DESCRIPTION OF SYMBOLS 10 Storage place of discharge 11 Discharge 20 Melting device 21 Inner pot 21a Raised bottom 21b Inner lid 21c Link mechanism 22 Outer cover 25 Outer pot 26 Solid matter separation filter 27 Partition flange 27a Through hole 28 Chimney 29 Exhaust gap 30 Desalination device DESCRIPTION OF SYMBOLS 31 Desalination part 32 Wax collection | recovery part 33 Connection path 34 Process gas discharge pipe 40 Cooling device 41 Cooling water tank 42 Pump 43 Primary cooler 44 Secondary cooler 50 Oil-water separation device 51 Oil-water collection tank 52 Filter 53 Oil-water separation tank 54 Oil / water separator 55 Pump 56 Oil refinery and fuel tank 60 Gas combustion furnace 61 Safety device 62 Cooling water tank 65 Excess gas combustion furnace 70 Crushing and sorting machine

Claims (5)

A processing plant for melting a predetermined effluent that can be liquefied,
The molten oil for melting the discharged matter is stored and the inner pot having a treatment space capable of charging the discharged matter and the inner pot are heated to keep the temperature of the molten oil stored in the inner pot at a predetermined temperature. A melting device with an outer pot for
A demineralizer for removing chlorine-based gas discharged from the melting apparatus;
A cooling device for cooling the exhaust gas from which the chlorine-based gas has been removed by the desalination device;
An oil and water recovery device that removes moisture and oil from the exhaust gas cooled by the cooling device;
A gas combustion furnace for burning unrecovered gas that has not been recovered by the oil-water recovery device,
The gas combustion furnace includes a combustion auxiliary body heated to a temperature higher than the combustion temperature of the unrecovered gas in order to completely burn the unrecovered gas,
The desalination apparatus includes a cylindrical desalination unit for detoxifying the chlorine-based gas, and a funnel-shaped wax recovery unit continuous to a lower portion of the desalination unit. , The exhaust heat of the melting device can be used through 400 degrees Celsius or more and through the chimney,
Between the inner pot and the outer pot in the melting device, an exhaust gap for exhausting combustion gas from the outer pot, and a chimney communicating from the exhaust gap to the outside of the outer pot,
Immediately below the chimney is provided with a partition flange that partitions the exhaust gap vertically.
The partition flange is provided with a large number of through-holes communicating with the upper and lower sides of the exhaust gap at equal intervals, and each through-hole is provided with a shutter so that the amount of communication at the position far from the chimney is larger than the position near the chimney. Effluent melting treatment plant formed to be adjustable. The inner pot has a raised bottom that rises from the bottom to the top,
The outer pot is provided with a raised bottom heating portion for applying thermal energy to a recess for forming the raised bottom portion,
2. The waste melting treatment plant according to claim 1, wherein the raised bottom portion is positioned so as to pass through an internal space far from a side surface of the inner pot.   The said inner pot is equipped with the solid substance separation filter which makes | forms the spider web shape for isolate | separating the residue which precipitates on a bottom face, and the solid substance which should be isolate | separated from the residue. Item 3. An emission melting treatment plant according to any one of Items 2 to 3. The inner hook has an inner lid that is movable from the upper side to the lower side along the inner surface forming the inner space thereof,
An exhaust lid melting processing plant according to any one of claims 1 to 3, further comprising an inner lid up-and-down moving mechanism for moving the inner lid up and down.   The said combustion auxiliary body is a mesh-shaped board | plate material produced with the stainless steel, Comprising: It heats and is built in 900 degreeC or more and 1200 degrees or less, The any one of Claims 1-4 characterized by the above-mentioned. Melting treatment plant for the described emissions.

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