JP2000279918A - Treatment of paint sediment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a paint sediment treatment process by which paint sediment and factory waste can concurrently and simply be treated without applying any load to the environment, to convert the paint sediment into a carbon material capable of being reutilized. SOLUTION: This treatment process comprises: mixing paint sediment with waste consisting of at least one material selected from sludge of phosphate- containing wastewater, sludge of general wastewater and incineration ash, to form a mixture; dehydrating the mixture so that the water content of the mixture is reduced to <=40%; then heating the dehydrated mixture without supplying any atmospheric gas, to convert the paint sediment into a carbon material; separating and removing magnetic substances contained in the carbon material, from the carbon material; and grinding the resulting carbon material into granular carbon having granule size corresponding to its intended application; wherein both the granular carbon and the magnetic substances separated and removed from the carbon material can be reutilized respectively.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for treating paint slag, and more particularly to paint slag generated in a painting process of an automobile body, sludge containing phosphate-containing wastewater, sludge from general wastewater, and incineration ash. At least one selected from the group consisting of
The present invention relates to a method for treating paint slag, wherein the waste is made up of a carbon or an inorganic compound and the waste is made of a metal or an inorganic compound by heating the mixture to form a mixture.

[0002]

2. Description of the Related Art The coating process of an automobile body is roughly divided into a degreasing process, a film forming process, and a film forming process.

That is, in a degreasing process, a vehicle body is immersed in an alkaline solution to remove oil and dust adhering to the vehicle body surface. Then, neutralize and wash with water.

[0004] Next, in a film forming step, the vehicle body is immersed in a treatment solution containing zinc ions and phosphate ions. By this immersion, a zinc phosphate film is formed on the vehicle body surface. This film improves the rust prevention effect of the car body,
In addition, it plays a role in improving the adhesion of the coating film formed in the next coating film forming step.

[0005] Next, in a coating film forming step, the coating material is sprayed from a coating apparatus onto the vehicle body to apply the coating material on the film. If the applied paint is dried and solidified, a coating film is formed. As the coating material, usually, a thermosetting resin such as an acrylic resin, a polyester resin, a polyurethane resin, a melamine resin, a urea resin, and a benzoguanamine resin as a main component, and further, a coloring pigment, an extender pigment, a dispersant, an ultraviolet absorber, and a dilution Those containing an agent or the like are used.

[0006] In the coating film forming step, it is desirable that all the paint sprayed from the coating apparatus be applied to the vehicle body. Paint (paint scum) is present. In general, since the coating film forming step is repeated a plurality of times, the amount of paint residue is considerable.

[0007] Paint scum is usually collected by water injected at high pressure and collected by accumulating in the pits with this water.

[0008]

The method of treating the collected paint residue is described in, for example, Japanese Patent Application Laid-Open No. 55-88.
No. 10, JP-B-7-102359, the incineration method, the heat treatment method, and the like are known.

However, in the case of incineration or heating the paint flocculate, since the main component of the paint flocculate is a thermosetting resin as described above, upon heating the CO and CO _2, more organic gas chloride Occurs. Therefore, it is hard to say that it is an environmentally preferable treatment method.

[0010] Further, not only paint scum but also sludge from phosphate-containing wastewater is discharged from the film forming step in the above-mentioned coating step, for example. That is, in the treatment solution containing zinc ions and phosphate ions used in the film forming step, iron phosphate and the like that are eluted from the vehicle and iron and phosphoric acid are combined with the increase in the number of times of film formation. Since the phosphate and zinc phosphate gradually precipitate, the treatment solution eventually becomes sludge. This sludge has no film forming ability and should be treated as waste.

In addition, incineration ash and the like, which are residues of incineration of sludge and garbage of waste washing water and the like (ie, general waste water) generated by washing the vehicle body after the degreasing step, are discharged. Should be disposed of as waste.

Generally, large-scale facilities are required to treat these wastes, and it is customary to outsource these treatments to a contractor. However, outsourcing has the disadvantage of increasing waste disposal costs.

Therefore, the paint residue and these wastes are simultaneously
And easily and easily from the paint residue CO or CO _Two, Organic chloride gas
If it can be processed without generating
Of waste and cost of waste disposal
It is thought that it can be. Further, such processing
Method to make these reusable
It is desirable from the viewpoint of resource saving. However
However, such processing methods have not been known so far.
Not.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and has been made in order to solve the above-mentioned problems, and to dispose of at least one selected from the group consisting of paint sludge and sludge containing phosphate, sludge of general wastewater, and incineration ash. By mixing and heating the waste, the paint slag can be made a reusable carbon aggregate, and the waste can be made of an inorganic compound or metal. _2. It is an object of the present invention to provide a method for treating paint scum without generating chlorinated organic gas.

[0015]

In order to achieve the above object, the present invention provides a first pulverizing step of pulverizing paint slag, the crushed paint slag, and a sludge containing phosphate-containing wastewater. A mixing step of mixing a waste consisting of at least one selected from the group consisting of wastewater sludge and incineration ash to form a mixture; a dehydration step of dehydrating the mixture to a water content of 40% or less; The method is characterized by comprising a carbonization step of heating the mixture obtained without supplying an atmospheric gas to convert the paint residue into a carbon material, and a second pulverization step of pulverizing the carbon material.

Examples of the paint scum include paint slag containing a thermosetting resin generated in a painting process of an automobile body.

In this treatment method, most of the thermosetting resin contained in the paint residue is converted into a solid granular carbon material, and no CO, CO ₂ , or organic chloride gas is generated. Therefore, the load on the environment is reduced.

In this case, after the carbonizing step or the second pulverizing step, a separating and removing step of separating and removing the magnetic substance contained in the carbon material from the carbon material may be performed. This magnetic material consists essentially of iron and can therefore be reused as iron.

On the other hand, the amount of metal or inorganic compound contained in the carbon material without being recovered is extremely small, and does not affect the physical properties of the carbon material. Therefore, the carbon material can be used as an aggregate, a body pigment, a deodorant, a fertilizer, or the like without separating the carbon material from the carbon material.

That is, the above-mentioned treatment method can simultaneously and simply treat paint scum and waste, and change the paint scum and waste itself into a reusable form. Therefore, waste disposal costs can be reduced and resources can be saved.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a method for treating paint scum according to the present invention will be described below in detail with reference to the accompanying drawings, together with the operation thereof.

FIG. 1 is a flowchart showing the flow of steps in the processing method according to the present embodiment. As shown in FIG. 1, the processing method according to the present embodiment includes a first pulverizing step S1, a mixing step S2, a dehydrating step S3, a carbonizing step S4, a separation removing step S5, a second Crushing process S6
And a classification step S7 if necessary.

In the present embodiment, as the paint residue, a resin mainly composed of a thermosetting resin such as an acrylic resin, a polyester resin, a polyurethane resin, a melamine resin, a urea resin, and a benzoguanamine resin is selected. The coating residue may further contain an organic solvent such as a thinner or a pigment. Further, water may be further contained. Examples of such paint scum include paint scum where unpainted paint is collected in the painting process of an automobile body.

First, in the first pulverizing step S1, the paint residue is pulverized by a pulverizer into a lump having an average diameter of about 5 mm. Specifically, as shown in FIG. 2, the paint residue 9 stored in the container 10 is put into a hopper 12, and the crusher 16 is conveyed by a conveyor 14 facing the bottom of the hopper 12.
Transport to The paint residue 9 roughly pulverized by the pulverizer 16 is then guided to a mixer 18 provided with a stirring blade. Waste is also introduced into the mixer 18, and when mixed with the waste in the mixing step S <b> 2 performed here, the massive paint scum 9 uniformly mixes with the waste. That is, the mixing step S2
In step (1), the crushed paint residue 9 is mixed with waste, that is, at least one selected from the group consisting of phosphate-containing wastewater sludge, general wastewater sludge, and incineration ash. This mixing causes the waste to adhere to the periphery of the clumped paint scum 9.

Here, the sludge of the phosphate-containing solution refers to the sludge of a solution containing a phosphate such as zinc phosphate or iron phosphate. The sludge of a treatment solution containing a phosphate ion and a zinc ion used in the film forming step, which is one of the methods, is mentioned as an example. Examples of general wastewater sludge include:
Examples include, but are not particularly limited to, general wastewater sludge from an automobile manufacturing plant in which waste washing water of an automobile body is collected. For example, sludge of wastewater such as washing water and bathing water discharged in the course of family life, dredging sludge at a civil engineering construction site, rainwater sludge, or a mixed sludge thereof may be used.

The above two sludges contain inorganic compounds and metals. Specifically, the sludge of the phosphate-containing solution contains a phosphate such as zinc phosphate or iron phosphate as described above. In addition, the sludge of general wastewater (general wastewater) of an automobile manufacturing plant contains iron, zinc, nickel, copper, and the like. Therefore, such inorganic compounds and metals can be obtained by removing water and volatile components from the sludge. Since the ratio of the other metal to iron is extremely small, the metal can be considered to be substantially iron.

The incineration ash is not particularly limited, but preferred examples thereof include paper, wood, garbage discarded from a kitchen, general waste such as plastic (thermoplastic resin), and the like.
Alternatively, ash obtained by incineration of these mixed wastes can be mentioned. The incineration ash contains moisture, the above-mentioned metals (substantially iron as described above), inorganic compounds, carbides and the like.

The mixing ratio between the paint slag 9 and the waste in the mixer 18 is such that the waste is 1 for 100 parts by weight of the paint slag.
It is preferable that the content be 0 parts by weight or more. Waste ratio is 1
If the amount is less than 0 parts by weight, the thermosetting resin, which is the main component of the paint scum 9, may adhere to the inner wall or the like of the heating device during heating in the carbonization step S4, and as a result, the heating device is closed. This is because it can happen. This mixer 18
The mixing is carried out by rotating the stirring blade while continuously mixing the paint scum 9 and the waste material substantially in the mixer 18.

When the mixing step S2 is completed, the mixture is continuously discharged from the outlet of the mixer 18 by the conveyor 20, and is conveyed to the next dehydration step S3. In the mixing step S2, the higher the water content of the paint slag 9 and the waste, the more uniformly they are mixed. Therefore, there is no need to dehydrate the paint residue 9 and the waste before the mixing step S2. Next, in the dehydration step S3, the water content is 40%.
The mixture is dewatered until: 40% moisture content
If the temperature is higher than the above range, it takes a long time to evaporate and evaporate the water when the mixture is heated in the carbonization step S4, so that the processing efficiency of the mixture is reduced. The dehydration method is not particularly limited, and any suitable dehydration device 22 may be used. Examples of the dehydration method include press dehydration using a filter press. The mixture thus dehydrated is further fed to a carbonization step by a conveyor 24.

In the carbonization step S4, the water content is 40
Heat the mixture, which has been dehydrated to below%. That is,
The mixture is heated by a heating device
Put in. The temperature at this time is preferably set to 350 to 550 ° C. If the temperature is lower than 350 ° C., the reaction rate of the paint scum 9 is low, so that the processing efficiency is low and the yield of carbon aggregate is low. If the temperature is higher than 550 ° C., even if a small amount of oxygen remains in the heating device, the carbon material is oxidized by the oxygen to generate CO ₂ . A more preferred temperature is 400-500 ° C. In fact, the heating device 26 comprises two parallel screw conveyors 28a, 2
8b and a heat source 30 below. The mixture having passed through the dehydration step S3 is supplied to a hopper 32 constituting the heating device 26.
While being conveyed by the screw conveyors 28a and 28b, and carbonized by dry distillation under the heating action of the heat source 30.

This heating is performed without supplying an atmospheric gas in order to prevent the oxidizing gas from being mixed into the heating device 26. When the mixture is heated in an atmosphere containing an oxidizing gas, the thermosetting resin, which is a main component of the paint scum 9, is easily oxidized to CO or CO ₂ , and is itself decomposed or combined with chlorine. Thereby, a chlorinated organic gas is generated, so that a carbon material cannot be obtained with a high yield.

By the heating, the organic solvent such as water and thinner evaporates from the paint residue 9, and the thermosetting resin remains as a residue. In addition, moisture evaporates and evaporates from sludge and incineration ash, leaving metals, inorganic compounds and carbides as residues, which remain on the surface of the thermosetting resin. Further, the pigment contained in the paint residue 9 changes to an inorganic compound.

After the volatile components evaporate and evaporate, the thermosetting resin starts to harden and becomes tacky. As a result, metals, inorganic compounds, and carbides are adhered to the surface of the thermosetting resin. That is, the surface of the thermosetting resin is covered with these. Further, a part of the metal, the inorganic compound, and the carbide is taken into the thermosetting resin having an adhesive property and is fused to the thermosetting resin.

During this heating, metals, inorganic compounds and carbides do not exhibit tackiness. Therefore, the thermosetting resin whose surface is covered by these does not adhere to the inner wall of the heating device 26 or the screw conveyors 28a and 28b. As a result, the paint residue 9 and waste can be continuously processed while being transferred in the heating device 26.

Finally, the thermosetting resin is carbonized to produce a carbon material. That is, since no oxidizing gas is present, the thermosetting resin is changed to a carbon material without generating CO, CO ₂ , or organic chloride gas. Therefore, the burden on the environment is significantly reduced as compared with the conventional method of heating or incinerating paint slag.

On the surface of the carbon material, a metal or an inorganic compound,
Carbides are attached, and some carbon materials contain metals, inorganic compounds, and carbides inside. Among the metals, the magnetic material can be separated and removed from the carbon material using the iron removing machine 36 in the separation and removal step S5. For example, if the carbon material discharged from the heating device 26 is exposed to the iron removing machine 36 using a magnet, the magnetic material attached to the surface of the carbon material is attracted by the magnetic force of the magnet and separated and removed from the carbon material. Is done. Then, the carbon material from which the magnetic material is separated and removed is discharged from the discharge port of the iron removing machine 36. The magnetic material separated and removed is discharged from another discharge port.

As described above, the metal can be substantially regarded as iron. Since iron is attracted to the magnet, in the present embodiment, the magnetic material separated and recovered can be regarded as substantially iron. Therefore, the collected magnetic material can be reused as iron.

Next, if the carbon material conveyed through the conveyor 38 is crushed by the crusher 40 in the second crushing step S6 to a particle size corresponding to the purpose and application, the crushed carbon material is formed of a fine-grained granular carbon material. A carbon aggregate is obtained.

If necessary, as shown in parentheses in FIG. 1, finely pulverized granular carbon may be classified in the classification step S7. In this case, by feeding and classifying the carbon aggregate to the classifier 42 via the conveyor 44, granular carbon having a narrow particle size distribution, that is, a substantially uniform particle size can be obtained. The granular carbon contains metals, inorganic compounds, and carbides that have not been separated and removed in the separation and removal step S5. However, since their contents are extremely small, they do not affect various properties of the granular carbon. Therefore, they can be used as a carbon material composed of the granular carbon aggregate without separating them from the granular carbon.

As described above, in the method for treating paint slag of the present embodiment, paint scum, sludge of a phosphate-containing solution,
Sludge of general wastewater and waste consisting of at least one selected from the group consisting of incineration ash can be treated very easily. Further, the thermosetting resin, which is the main component of the paint residue, can be almost carbonized, and the carbon material can be obtained with a high yield.

The carbon material obtained by the above processing method is
It can be used as aggregate for concrete or mortar. That is, if this carbon material is kneaded together with cement or sand, and then hardened, the hardened concrete or mortar has a higher strength than that without the carbon material added.

The carbon material can be used as an extender. For example, by adding this carbon material to a printing ink or paint, the hue and tinting strength thereof can be adjusted to desired ones.

Further, this carbon material is porous and has a large specific surface area, and therefore can be a substitute for activated carbon. That is, it can be used as a deodorant, an adsorbent, and the like.

Furthermore, this carbon material can be used as a fertilizer for plants.

On the other hand, as described above, the separation and removal step S5
The magnetic material (substantially iron) separated and recovered in
It can be used as iron.

As described above, the produced carbon material and the separated and recovered iron can be reused, and therefore, resource saving can be achieved.

In the above embodiment, the iron removing machine 36 is used.
The step S5 for separating and removing magnetic substances such as iron by the carbonization step S4
, But not after the carbonization step S4, but in the second
(See the broken line in FIG. 2).

[0048]

As described above, according to the method for treating paint slag according to the present invention, at least one selected from the group consisting of paint slag, phosphate-containing wastewater sludge, general wastewater sludge, and incineration ash. A single waste can be treated very simply. In addition, when heating paint residue, CO and C
O ₂ and chlorinated organic gas are not generated. Therefore, the effect of reducing the disposal cost of the waste and reducing the burden on the environment can be achieved.

Further, according to the method for treating paint slag of the present invention, the paint scum can be made of reusable granular carbon such as concrete or mortar aggregates and extender pigments, and can be made of waste materials. It is possible to reuse the magnetic material separated and recovered. Therefore, resource saving can be achieved.

[Brief description of the drawings]

FIG. 1 is a flowchart showing steps of a method for treating paint residue according to the present embodiment.

FIG. 2 is an overall schematic explanatory view of equipment for treating paint scum by the method for treating paint scum according to the present embodiment.

[Explanation of symbols]

9 ... paint residue 16 ... crusher 18 ... mixer 22 ... dehydration device 26 ... heating device 36 ... iron removal machine 40 ... crusher 42 ... classifier

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 4D004 AA36 AA50 BA02 BA04 CA04 CA08 CA13 CA15 CA26 CB02 CB26 CB34 CB46 4D059 AA03 AA09 AA19 BB05 BE16 BJ01 CB06 CB07 CC01 CC04 CC06 CC10 DA64 DB11 EB01

Claims (5)

[Claims] 1. A first pulverizing step for pulverizing paint slag, at least one selected from the group consisting of the crushed paint slag, phosphate-containing wastewater sludge, general wastewater sludge, and incineration ash. A mixing step of mixing the waste with a waste consisting of: a dehydrating step of dehydrating the mixture to a water content of 40% or less; and heating the dehydrated mixture without supplying an atmosphere gas. A carbonization step of using the paint slag as a carbon material; and a second pulverization step of crushing the carbon material. 2. The method for treating paint slag according to claim 1, further comprising, after the carbonization step, a separation and removal step of separating and removing a magnetic substance contained in the carbon material from the carbon material. Method of treating paint slag. 3. The method for treating paint slag according to claim 1, further comprising a separation / removal step of separating / removing the magnetic material contained in the carbon material from the carbon material after the second pulverization process. A method for treating paint scum, characterized by the following. 4. The method according to claim 1, further comprising a classifying step of classifying the pulverized carbon material after the second pulverizing step. Method of treating paint scum. 5. The method for treating paint scum according to claim 1, wherein said paint scum is a paint scum containing a thermosetting resin generated in a painting process of an automobile body. A method for treating paint scum, characterized by the following.