KR20100024153A - The treating apparatus of waste insulating oil with polychlorinated biphenyls and the treating method thereof - Google Patents

Abstract

PURPOSE: An apparatus for processing waste insulating oil in which polychlorinated biphenyl is contained is provided to environment-friendlily discharge the waste insulating oil by purifying the polychlorinated biphenyl component through an exhaust gas disposal part. CONSTITUTION: An apparatus for processing waste insulating oil in which polychlorinated biphenyl is contained comprises: an pre-treatment tank(2) which stores waste insulating oil and preheats the oil; a reaction bath(10) in which metallic sodium is melted and the melted sodium is desalted by chemically reacting with the polychlorinated biphenyl contained in the waste insulating oil; a post-treatment bath(21) which sends the waste insulating oil to a processed oil reservoir(24) and sends sodium chloride and all kinds of the precipitates to a separation collecting tub(27); and an exhaust gas disposal part(32) which desalts the polychlorinated biphenyl included in exhaust gas and discharges the gas.

Description

The treating apparatus of waste insulating oil with polychlorinated biphenyls and the treating method

The present invention relates to an apparatus and method for environmentally harmless decomposition of waste insulating oil containing polychlorinated biphenyls (PCBs), and more particularly, to conventional waste transformers, capacitors, safety devices, circuit breakers, etc. The pre-treatment tank containing the polychlorinated biphenyl containing polychlorinated biphenyl from the vessel of the pre-treatment tank is stored and preheated to a predetermined temperature, and the pre-heated waste insulating oil from the pretreatment tank is transferred and stored in a predetermined amount. A reaction tank which is heated to a predetermined temperature in an input state and mixed with stirring while the metal sodium is melted, and polychlorinated biphenyl and molten sodium contained in the waste insulating oil are chemically desalted and desalted waste insulating oil from the reaction tank. Chloride produced during desalting by cooling at room temperature while stored The waste insulating oil floated on the upper part with the small specific gravity while allowing the precipitate and various precipitates to be precipitated is sent to the treatment oil storage tank, and the sodium chloride and various precipitates precipitated due to the high specific gravity are sent to the separate recovery tank, and the chloride or nasal transferred from the after treatment tank. Separation recovery tank for filtering the sodium and various precipitates with a sieve provided therein to maintain the temperature inside the melting point of the sodium metal so that the metal sodium contained in the precipitate is remelted and sent back to the reactor for reuse. The exhaust gas generated from the tank, the reaction tank, and the after-treatment tank is passed through the exhaust gas processor in which the liquid sodium is stored at a certain level so that the polychlorinated biphenyls contained in the exhaust gas are desalted and filtered by a purifying filter. Characterized in that consisting of the exhaust gas processing unit to be discharged Poly relates to an apparatus and method for processing waste transformer oil containing the polychlorinated biphenyl that.

Polychlorinated biphenyls (PCBs) are widely used for insulating oils, heating mediums, lubricants, and plasticizers, and thus have high value for use. Therefore, as a substance used for various purposes, it is basically a compound in which hydrogen bonded at ten hydrogen atom positions in biphenyl (C ₆ H ₅ -C ₆ H ₅ ) is substituted with 1 to 10 chlorine atoms. There may be 242 kinds of isomers, but about 100 kinds of isomers are actually used as insulations of electrical products such as transformers and capacitors because they are not decomposed even when heated and insoluble in water and have excellent electrical insulation.

However, polychlorinated biphenyls are introduced into sewage treatment plants after use, causing environmental destruction and changes in ecosystems. Since these polychlorinated biphenyls are used without any environmental measures, they are gradually identified as serious pollutants. Its production and use has been stopped worldwide, but in the world, 1 million tons of polychlorinated biphenyls have been released to nature, and the disposal and disposal amount is 2 million tons. It is known that there is an urgent need for an efficient decomposition method thereof.

Currently, according to the US EPA, more than 90 kinds of technologies are reported to be able to process polychlorinated biphenyls. Until now, technologies for treating harmful chemicals such as polychlorinated biphenyls are largely biochemical treatment technologies, It is known that there are thermal treatment techniques, physical or chemical treatment techniques, and the like.

In the case of biological treatment using an enzyme or the like which is effective in treating polychlorinated biphenyls, it is applicable to various media contaminated with polychlorinated biphenyls and has the advantage of minimizing the generation of residues. The disadvantage is that the efficiency is greatly influenced by the polychlorinated biphenyl concentration.

The thermal treatment technology has advantages in that the processing speed is high and the volume of the treated waste is small. However, it is limited to be applied to liquid and gaseous media, which is relatively expensive, and requires further treatment of residues generated after the treatment. In case of incineration of polychlorinated biphenyl-containing products in a general manner, polychlorinated biphenyls are reported to be produced as by-products such as dioxin and polycyclic aromatic hydrocarbons, which are more toxic than polychlorinated biphenyls. There is a limit to the safe handling of insulating oils. In particular, since it is known that harmful dioxins are produced and discharged, due to the strong opposition of residents in the area where incinerators are installed, they are often exported to foreign countries for consignment or long-term storage. There is also a high risk that biphenyl chloride will be released into the environment and contaminate the environment.

Decomposition by ultraviolet light has a disadvantage of low decomposition efficiency, and chemical decomposition by oxidizing agent can decompose in several hours, but corrosion of device material by oxidizing agent is a problem, and oxidative decomposition by supercritical water consumes energy. There is a problem that is too large.

In addition, in the case of chemical treatment technology, there is a disadvantage that additional treatment of residues generated after treatment is required like thermal treatment technology, but the treatment speed is fast and can be applied to various media contaminated with polychlorinated biphenyls. It is also possible to process phenyl and can be utilized as recycling technology.

Chemical decomposition reactions of commercialized polychlorinated biphenyls include metal sodium dispersion method (North Hokkaido), dechlorination method (Toyoda, Japan), and alkaline catalyst decomposition method (USA, Japan, Australia). Hydrogenated dechlorination catalyst reaction method (Osaka, Japan) Dehydrochlorination (Kyushu, Canada), hydrothermal oxidation (Tokyo, Japan), organometallic alkali decomposition (Japan), chemical extraction (Japan) and supercritical hydroxide (U.S., Japan).

On the other hand, Japanese Patent Application Laid-Open No. 10-316798 discloses desalination by adding ethyl alcohol, ethylene glycol, and alkaline hydroxide to insulating oil containing polychlorinated biphenyl to treat polychlorinated biphenyl contained in insulating oil. Japanese Patent Laid-Open No. 2001-29942 discloses a method for treating polychlorinated biphenyls contained in insulating oil using titanium oxide as a photocatalyst.

In the process of the Japanese commercialization company using the metal sodium dispersion method for chemical dechlorination decomposition reaction, a large building with an area of about 24000㎡ is used to process 0.5 tons of insulating oil including polychlorinated biphenyls in one day. The pre-treatment process is to insulate the oil from the transformer and to carry out vacuum heating separation process to remove the polychlorinated chlorinated silil attached to the transformer from the transformer, crush the transformer, and then clean the transformer member. Is a process of treating polychlorinated biphenyls by adding metallic sodium to insulating oil. In this case, the complex of the pretreatment process has a disadvantage that a large site factory is required, and equipment costs such as vacuum facilities are generated at a high cost, and polychlorinated biphenyl components are leaked in the process of cleaning after crushing the transformer.

The present invention is to solve the above problems, while treating the insulating oil containing polychlorinated biphenyls by chemical decomposition treatment method using the metal sodium dispersion method, sodium chloride and various precipitates which are reaction products generated in the reaction tank and the after-treatment tank. It effectively removes the manure from the separate recovery tank and simultaneously recovers and reuses the dechlorination reagent metal sodium, which is introduced into the reaction tank, through the separation recovery tank to increase the treatment efficiency. Chlorinated biphenyl is purified in an exhaust gas treatment unit equipped with an exhaust gas processor, a plasma heating tube, and a purification filter, and is discharged in an environmentally harmless state. Also, each container containing polyvinyl chloride biphenyl containing insulating oil is compressed. Cleaned with air and dechlorinated reagents and heated in a high temperature furnace Heating the gas to screen the inner surface of polychlorinated biphenyl component in solid form in a clutching of the container and to it is an object to be processed to purify the exhaust gas directed to the processing unit.

In order to achieve this purpose, a pretreatment tank for storing and preheating a predetermined amount of waste insulating oil containing polychlorinated biphenyls from a container such as a conventional waste transformer, a condenser, a safety device, or a breaker and preheating it to a predetermined temperature; The preheated waste insulating oil is transferred and stored in a certain amount. The sodium chloride, a dechlorinated reagent, is heated and then heated to a certain temperature, and the metal sodium is melted and mixed. The polychlorinated biphenyl and molten sodium contained in the waste insulating oil are chemically mixed. The reaction tank for reacting and desalting the waste, and the waste insulating oil desalted from the reaction tank is transferred and cooled in room temperature in a predetermined amount, so that sodium chloride and various precipitates generated during the desalting process are precipitated, and the specific gravity is small. The insulating oil is sent to the treatment oil storage tank and the specific gravity is large, Sodium sulfide and various precipitates are filtered through a post-treatment tank sent to a separate recovery tank, and the sodium chloride and various precipitates transferred from the post-treatment tank are filtered through a filtering net provided therein, and the internal temperature is maintained above the melting point of the metal sodium and included in the precipitate. Separation recovery tank for reusing and recovering the molten metal sodium is sent to the reaction tank and reused, and exhaust gas generated in the pretreatment tank, the reaction tank and the after-treatment tank through an exhaust gas treatment device in which liquid sodium is stored at a predetermined level. The polychlorinated biphenyl contained in the desalination treatment and filtering by a purifying filter is configured as an exhaust gas processing unit for discharging the purified gas has a feature of the present invention.

As described above, according to the present invention, while treating the insulating oil containing polychlorinated biphenyl by the chemical decomposition treatment method using the metal sodium dispersion method, sodium chloride and various precipitates generated in the reaction tank and the after-treatment tank are effectively used in a separate recovery tank. Simultaneously removing the manganese, which is a dechlorination reagent that is added to the reaction tank, can be recovered and reused through the separation recovery tank to improve the overall treatment efficiency, and polychlorination in the exhaust gas generated from the pretreatment tank, the reaction tank, and the after treatment tank. The biphenyl component can be purified and discharged in an environmentally harmless state by purifying the exhaust gas treatment unit equipped with an exhaust gas processor, a plasma heating tube, and a purification filter, and each container containing insulating oil containing polychlorinated biphenyls can be discharged. Clean with compressed air and dechlorination reagent There is an effect that can be heated to a gas screen polychlorinated biphenyl component in solid form which stuck to the inner surface of the container and a simple process harmless to the purification treatment as in an environmentally sound sent to the exhaust gas processing portion.

Hereinafter, the preferred configuration according to the present invention will be described in detail with reference to the drawings.

The waste insulating oil treatment apparatus 1 according to the present invention includes polychlorinated biphenyls (PCBs) used for insulation of waste transformers, capacitors, safety devices, and circuit breakers, as shown in FIGS. 1 to 4. As a device for environmentally harmless decomposition of waste insulating oil, waste insulating oil containing polychlorinated biphenyl from a container 4 such as a conventional waste transformer, a condenser, a safety device, or a breaker is charged and stored at a constant temperature. The pretreatment tank 2 to be preheated, and the preheated waste insulating oil from the pretreatment tank 2 are transferred and stored in a predetermined amount, and warmed to a predetermined temperature in a state where a dechlorination reagent, metal sodium, is added to melt the metal sodium. A reaction tank (10) for chemically reacting and desalting polychlorinated biphenyl and molten sodium contained in the waste insulating oil by stirring and desalting from the reaction tank (10) Waste insulation oil is transferred to a predetermined amount and stored at room temperature in a stored state to allow sodium chloride and various precipitates to be precipitated during desalting to precipitate, and the waste insulation oil floated on the upper portion is sent to the treatment oil storage tank 24 and the specific gravity is large. Sodium chloride and various precipitates are filtered through a post-treatment tank 21 sent to a separate recovery tank 27, and sodium chloride and various precipitates transferred from the post-treatment tank 21 by a filtering net 29 provided therein. Separation and recovery tank 27 and the pre-treatment tank 2 and the reaction tank 10 to be kept warm above the melting point of the noble metal sodium to be remelted and recovered by re-melting and sent to the reaction tank (10) And polychlorination contained in the exhaust gas by passing the exhaust gas generated from the after-treatment tank 21 through the exhaust gas processor 33 in which the liquid sodium is stored at a predetermined level. The biphenyl is desalted, and the exhaust gas treatment unit 32 is configured to filter the filtered filter 34 to discharge the purified gas.

The pretreatment tank 2 is a predetermined cylindrical casing as shown in FIG. (Iii) A pretreatment tank inlet 5 through which the waste insulation oil flows is formed, and a predetermined amount of waste insulation oil flows into and is stored in the pretreatment tank 2, and a normal heating heater 6a is installed inside the vessel. Preheat the waste insulating oil introduced into about 50 ~ 70 ℃ to pre-treat the chemical reaction in the reaction tank 10 in a short time, and the pre-treatment tank outlet 7 is formed on the other side lower pre-treated waste Insulating oil is sent to the reaction tank 10, and a flow rate sensor 8a is installed inside the upper side of the other side of the pretreatment tank 2. It is to control the operation of the inflow pump (3) so that the waste insulating oil generated from the oil is no longer introduced.

In addition, the pretreatment tank 2 has a pretreatment tank gas outlet 9 formed at the top of the other side to send various exhaust gases including oil vapor and moisture generated during preheating to the exhaust gas treatment unit 32.

The reactor 10 is a predetermined cylindrical casing as shown in Figs. 1 and 2 and the reaction tank inlet 11 through which the pre-heated waste insulating oil from the pretreatment tank 2 is introduced is formed at one upper portion. A predetermined amount of pretreated waste insulating oil is introduced into and stored inside, and a normal heating heater 6b is installed inside to heat the waste insulating oil introduced into the vessel to about 100 to 150 ° C. (12) is formed, the metal sodium, which is a dechlorination reagent, is introduced into the reaction tank 10, and the molten metal sodium having a melting point of 97.9 ° C is melted, and the molten liquid sodium is chemically formulated with polychlorinated biphenyls contained in waste insulating oil. The reaction is to be dechlorinated, and the inner center portion is equipped with a vertically stirrer (13), so that the sodium and chlorine dechlorination reagent injected into the waste The condensed milk is to be stirred and mixed evenly, but the lower surface of the reaction tank 10 is formed as an inclined surface 14 inclined downward in one direction as shown in FIG. Sodium is collected along the inclined surface 14 to the lower side of one side of the reaction vessel 10, and the secondary stirrer 15 is installed vertically inside the lower side of the one side of the reaction vessel 10 and flows down along the inclined surface 14. It is intended to melt the metal sodium in a short time by intensive stirring.

The reactor 10 has a reaction tank outlet 16 formed at an upper side than the inclined surface 14 at the lower side of the reaction tank 10 to send desalted waste insulating oil to the post-treatment tank 21. The other side upper inner side is provided with a flow rate sensor (8b), if a predetermined amount of pre-heated waste insulating oil from the pre-treatment tank 2 is detected, the pre-treatment tank outlet 7 and the reaction tank inlet 11 of the pre-treatment tank (2) By controlling the operation of the transfer pump (18a) installed between the pipe (17a) connecting between the preheating waste oil from the pre-treatment tank (2) to control no more inflow, the other side of the reactor (10) A reactor gas outlet 19 is formed at the uppermost portion to send various exhaust gases including oil vapor and water generated during the desalination reaction to the exhaust gas treatment unit 32.

In addition, the reaction tank 10 has a precipitate outlet 20a formed at one side of the lower side of the inclined surface 14, which is formed as a reaction product during the desalination process, and includes solid sodium chloride (NaCl) and unmelted metal sodium precipitated at the bottom. Various deposits are sent to the separation recovery tank 27 through a transfer pump 18b.

The after-treatment tank 21 is a cylindrical casing having a lower portion formed in a cone shape as shown in FIGS. 1 and 3, and a post-treatment in which desalted waste insulating oil from the reactor 10 flows into one upper portion. The crude oil inlet 22 is formed so that a predetermined amount of desalted waste insulating oil is stored and stored therein, and a predetermined amount of desalted waste insulating oil stored therein is maintained at room temperature for 3 to 4 hours while being generated during desalination. Various precipitates including solid sodium chloride and metal sodium produced as the unreacted molten sodium remaining in the reaction tank 10 is recrystallized, are to be precipitated. The other side of the after-treatment tank 21 is post-treated. The crude outlet 23 is formed so that the specific gravity is small so that the waste insulating oil floated on the upper side is sent to the treatment oil storage tank 24, and the sediment outlet 2 0b) is formed so that the specific gravity is large, so that the sodium chloride, sodium metal, and various precipitates precipitated at the lower portion are sent to the separation recovery tank 27.

The waste insulating oil desalted and the precipitate removed to the treated oil storage tank 24 is used as regenerated oil after refined treatment according to a conventional method.

In addition, a flow rate sensor 8c is installed inside the upper portion of the other side of the after-treatment tank 21. When a predetermined amount of the desalted waste insulating oil from the reaction tank 10 is introduced and sensed, the reaction tank outlet of the reaction tank 10 ( 16) to control the operation of the transfer pump (18a) installed between the pipe (17b) connecting between the after-treatment tank inlet 22 so that the desalted waste insulating oil from the reaction tank 10 is no longer introduced. The post-treatment tank gas outlet 25 is formed at the top of the other side of the post-treatment tank 21 so that various exhaust gases including oil vapor and water generated in the post-treatment tank 21 may be discharged. 32).

In addition, the after-treatment tank 21 has a drain discharge port 26 that is opened and closed by a normal valve at the lower end formed in the shape of a cone, after the post-treatment, the outside of the various residues remaining in the after-treatment tank 21 It is to be discharged to and treated.

The separation recovery tank 27 is a predetermined tubular casing as shown in Figure 1 and the separation recovery tank inlet 28 is formed at one upper portion from the after-treatment tank 21 and the reaction tank 10 Various precipitates containing sodium chloride and sodium metal which are reaction products of the pipe 17c connect the sediment discharge ports 20a and 20b and the separate recovery tank inlet 28 of the after-treatment tank 21 and the reaction tank 10. It is transported by the transfer pump 18b installed in between to be introduced into the inner portion and the inner middle portion is provided with a strainer 29 so that the sediment, such as sodium chloride in the solid state in the strainer 29 is filtered out to be removed. However, on the outer circumferential surface of the separation recovery tank 27, a heating means 30a, such as a conventional banding heater, is installed so that the internal temperature is kept warm above the melting point (97.9 ° C.) of the metal sodium and included in the precipitate. In sodium are to be re-melted and is recovered through the recovery of sodium metal sphere 31 formed at the other side with a lower reuse dechlorination reagent is sent to the dechlorination reagent inlet 12 of the tank 10.

As shown in FIGS. 1 and 4, the exhaust gas treatment unit 32 discharges gas generated in the pretreatment tank 2, the reaction tank 10, and the aftertreatment tank 21 to the exhaust gas processor 33 and the purification filter. Purifying through the 34 to remove the polychlorinated biphenyl contained in the exhaust gas to be discharged to the atmosphere in an environmentally harmless state, the pretreatment tank (2) and the reaction tank (10) and the post-treatment tank ( 21, the exhaust gas is collected and flows into the gas inlet pipe 35 of the exhaust gas processor 33. The exhaust gas processor 33 has molten liquid sodium, which is a dechlorination reagent, at a predetermined level. It is stored and the lower part of the gas inlet pipe 35 is located in a state locked to the inside of the liquid sodium so that the exhaust gas introduced into the gas inlet pipe 35 is passed through the liquid sodium chloride containing polychlorinated ratio Phenyl reacts chemically The desalination treatment is performed, and a gas discharge port 36 is formed at an upper portion of the exhaust gas treatment unit 33 so that the desalted exhaust gas is discharged through the gas discharge port 36, and the purification filter 34 is made of ordinary activated carbon. It is to be discharged to the atmosphere in an environmentally harmless state in the filtered state through.

The exhaust gas treatment unit 33 has a heating means 30b, such as a conventional bending heater, is installed on the outer circumferential surface thereof so that the temperature inside the liquid is maintained at a temperature above the melting point (97.9 ° C.) of the metallic sodium, and the liquid is filled at a predetermined level therein. Sodium does not crystallize to a solid state.

In addition, according to another embodiment of the present invention, the exhaust gas treatment unit 32 is connected to the plasma heating tube 37 between the exhaust gas processor 33 and the purification filter 34, thereby providing the exhaust gas processor 33. As the first desalted exhaust gas passes through the plasma heating tube 37 heated at an extremely high temperature of about 1000 to 1500 ° C., polychlorinated biphenyls and various harmful gas components are thermally decomposed and burned. have.

Meanwhile, a container 4 such as a conventional waste transformer, a condenser, a safety device, a breaker, etc., in which an insulating oil containing polychlorinated biphenyl is contained and removed, is compressed air and a dechlorinated reagent as shown in FIG. 4. 4) The inside is first cleaned and heated to the boiling point of the polychlorinated biphenyl in a conventional heating furnace 38 to vaporize the solid polychlorinated biphenyl component adhering to the inner surface of the vessel 4. It is sent to the exhaust gas treatment unit 32 to be purified, but the heating furnace 38 is provided with an opening and closing door 39 on one side to inject and recover the container 4 therein, and the heating furnace ( 38, an external air inlet 40 having a normal blower 41 is formed at one upper portion thereof, and an exhaust gas exhaust 42 is formed at the other upper portion thereof, so that the internal temperature of the heating furnace 38 is increased. Higher than the boiling point of biphenyl (275 ~ 360 ℃) It is made to vaporize the solid polychlorinated biphenyl component adhering to the inner surface of the container 4 while being heated to a temperature of about 300 to 400 ° C., and the exhaust gas generated at this time is discharged from the blower 41. It is sent to the exhaust gas treatment unit 32 through the exhaust gas exhaust port 42 by the blowing operation so as to be purified.

Hereinafter, the action according to the present invention is as follows.

By using the waste insulating oil treatment apparatus 1 according to the present invention, the waste insulating oil containing polychlorinated biphenyl which is filled in the container 4 such as a conventional waste transformer, a condenser, a safety device, and a breaker is desalted. In the case of friendly and harmless decomposition treatment, as shown in FIG. 1, waste insulating oil containing polychlorinated biphenyls filled in each container 4 is oil-repelled by the inflow pump 3, and the pretreatment tank ( 2) the waste insulating oil is preheated to about 50 ~ 70 ℃ by heating operation of the heating heater (6a) installed inside the pretreatment tank (2) when a predetermined amount of waste insulating oil flows into the pretreatment tank (2) Pre-treatment so that the chemical reaction takes place in a fast time in (10), the preheated waste insulating oil is sent from the pretreatment tank (2) to the reaction tank (10) by the operation of the transfer pump (18a) and a predetermined amount to the reaction tank (10) Preheated waste insulating oil 2, the waste insulating oil is heated to about 100 to 150 ° C. by the heating operation of the heating heater 6b installed in the reactor 10, and the dechlorination reagent inlet 12 of the reactor 10 is heated. While a predetermined amount of metal sodium, a dechlorination reagent, was added and melted, the waste insulating oil containing polychlorinated biphenyl and molten sodium were evenly stirred and mixed by an agitator 13 installed vertically in the inner center portion of the reactor 10. Polychlorinated biphenyls and sodium are desalted by chemical reaction, and the lower surface of the reaction vessel 10 is inclined surface 14 formed to be inclined downward to one side, so that metal sodium which is not initially melted among the metallic sodium introduced into the inclined surface ( 14) to the lower side of the reaction tank 10 is gathered to one side of the lower side of the reaction tank 10, the auxiliary stirrer 15 is installed vertically in the inclined The metallic sodium flowing down the surface 14 is intensively stirred and melted in a short time.

The waste insulating oil desalted in the reaction tank 10 is sent to the after-treatment tank 21 by the operation of the transfer pump 18a and collects sodium chloride and unmelted metal sodium, which are reaction products collected at the bottom of the reaction tank 10. Various deposits, including various deposits, are sent to a separate recovery tank 27 by the operation of the transfer pump 18b, and as shown in FIG. Various precipitates including solid sodium chloride produced during desalting and unreacted molten sodium remaining in the reactor 10 were recrystallized while being maintained for 3 to 4 hours at precipitation, and the specific gravity was small. The waste insulating oil floated on the upper side is sent to the treatment oil storage tank 24 and used as regenerated oil after being refined according to a conventional method. The various precipitates are sent to the separation recovery tank 27 by the operation of the transfer pump 18b, the reaction tank 10 and the after-treatment tank 21 sent to the separation recovery tank 27 through the transfer pump 18b. Various precipitates containing sodium chloride and sodium metal, which are reaction products, are removed from the solid state sodium chloride and various precipitates by a filtering net 29 installed inside the separation recovery tank 27. The separation recovery tank ( On the outer circumferential surface of 27), heating means 30a, such as a conventional banding heater, is installed so that the internal temperature is kept warm above the melting point (97.9 ° C) of the metal sodium, and the metal sodium contained in the precipitate is remelted and the metal sodium recovery is recovered. Recovered through the sphere 31 is sent to the dechlorination reagent inlet 12 of the reactor 10 to be reused as a dechlorination reagent.

In addition, the exhaust gas generated in the pretreatment tank 2, the reaction tank 10 and the after-treatment tank 21 is an exhaust gas treatment unit comprising an exhaust gas processor 33, a plasma heating tube 37, and a purification filter 34 ( 32) The polychlorinated biphenyl contained in the exhaust gas is purged and discharged to the atmosphere in an environmentally harmless state, and the exhaust gas is stored in a molten liquid sodium, a dechlorination reagent, at a predetermined level. The polychlorinated biphenyls contained in the exhaust gas are chemically reacted with the liquid sodium and desalted by passing through the exhaust gas treatment unit 33 installed with the lower portion of the gas inlet pipe 35 submerged inside the liquid sodium. The exhaust gas passing through the exhaust gas treatment unit 33 passes through the plasma heating tube 37 heated at an extremely high temperature of about 1000 to 1500 ° C., and the polychlorinated biphenyl and various harmful gas components are heated secondarily. It is decomposed and burned, and is discharged to the atmosphere in an environmentally harmless state in a filtered state through a purification filter 34 made of ordinary activated carbon or the like.

Meanwhile, a container 4 such as a conventional waste transformer, a condenser, a safety device, a breaker, etc., in which an insulating oil containing polychlorinated biphenyl is contained and removed, is compressed air and a dechlorinated reagent as shown in FIG. 4. 4) The inside of the vessel 4 is first washed and heated to about 300 to 400 ° C., which is a temperature higher than the boiling point (275 to 360 ° C.) of the polychlorinated biphenyl in a conventional heating furnace 38. The adhered solid polychlorinated biphenyl component is vaporized and the generated exhaust gas is sent to the exhaust gas treatment unit 32 for purification.

1 is a schematic view showing the overall processing of the waste insulating oil treatment apparatus according to the present invention

Figure 2 is a schematic cross-sectional view of the reaction tank in the waste insulating oil treatment apparatus according to the present invention

Figure 3 is a schematic cross-sectional view of the after-treatment tank in the waste insulating oil treatment apparatus according to the present invention

4 is a schematic diagram of a state in which a container containing waste insulating oil is purged in the waste insulating oil treatment apparatus according to the present invention.

Description of the Related Art

1. Waste insulating oil treatment device 2. Pretreatment tank

3. Inlet pump 4. Container

5. Pretreatment tank inlet 6a, 6b. Heating heater

7. Pretreatment tank outlets 8a, 8b, 8c. Flow sensor

9. Pretreatment tank gas outlet 10. Reactor

11. Reactor tank inlet 12. Dechlorine reagent inlet

13. Agitator 14. Slope

15. Auxiliary Agitator 16. Reactor Outlet

17a, 17b, 17c. Piping 18a, 18b. Transfer pump

19. Reactor gas outlets 20a, 20b. Sediment outlet

21. Post-treatment tank 22. Post-treatment tank inlet

23. Post-treatment tank outlet 24. Treatment oil storage tank

25. Post-treatment tank gas outlet 26. Drain outlet

27. Separate recovery tank 28. Separate recovery tank inlet

29. Filtering nets 30a, 30b heating means

31. Metal sodium recovery port 32. Exhaust gas treatment part

33. Exhaust gas processor 34. Purification filter

35. Gas inlet pipe 36. Gas outlet

37. Plasma heating tube 38. Heating furnace

39. Opening and closing door 40. External air inlet

41. Blower 42. Exhaust gas exhaust

Claims (11)

A pretreatment tank (2) for storing a predetermined amount of waste insulating oil containing polychlorinated biphenyl from a waste transformer (4) of a transformer, a condenser, a safety device, and a breaker and preheating it to a predetermined temperature, and from the pretreatment tank (2). The preheated waste insulating oil is transferred and stored in a predetermined amount. The sodium chloride, which is a dechlorination reagent, is heated and then heated to a predetermined temperature, and the metal sodium is melted and mixed. The polychlorinated biphenyl and molten sodium contained in the waste insulating oil are mixed. The reaction tank 10 to be chemically reacted and desalted, and the desalted waste insulating oil from the reactor 10 is transferred and cooled at room temperature in a predetermined amount stored so that sodium chloride and various precipitates generated during desalting are precipitated. The waste insulation oil floated on the upper part with small specific gravity is sent to the treatment oil storage tank 24, and the sodium chloride and various precipitates precipitated due to its high specific gravity. The internal temperature of the metal sodium melting point while filtering the after-treatment tank 21 to be sent to the separate recovery tank 27 and the filtering net 29 provided therein with sodium chloride and various deposits transferred from the after-treatment tank 21. Separation recovery tank 27 and the pretreatment tank 2, the reaction tank 10 and the post-treatment, which are kept warm to a higher temperature so that the metal sodium contained in the precipitate is remelted and recovered and sent to the reactor 10 for reuse. By passing the discharge gas generated in the tank 21 through the discharge gas processor 33, the liquid sodium is stored at a certain level therein so that the polychlorinated biphenyl contained in the discharge gas is desalted and filtered by a purification filter 34. A waste insulating oil processing apparatus containing polychlorinated biphenyls, characterized in that the exhaust gas treatment unit 32 for discharging the purified gas. The pretreatment tank inlet (5) according to claim 1, wherein the pretreatment tank (2) has a tubular casing, and at one side, a pretreatment tank inlet (5) into which waste insulating oil discharged from the vessel (4) is introduced by an inflow pump (3). The heating heater 6a is installed to preheat the waste insulating oil introduced therein so as to pre-treat the chemical reaction in the reaction tank 10 within a short time, and the pretreatment tank outlet 7 is formed at the lower side of the other side. There is a pre-heated waste insulating oil is to be sent to the reaction tank 10, the other side upper inside of the pre-treatment tank (2) is installed a flow rate sensor (8a) is a predetermined amount of waste insulating oil flows into the container (4) In order to control the operation of the inflow pump (3) so that the waste insulating oil generated from the) is no longer introduced, the pretreatment tank gas outlet (9) is formed at the top of the other side of the pretreatment tank (2) A waste insulating oil processing apparatus containing polychlorinated biphenyls, characterized in that for sending various waste gases generated during preheating to the waste gas treatment unit (32). The reactor 10 according to claim 1, wherein the reactor 10 is a tubular casing, and a reaction tank inlet 11 through which the preheated waste insulating oil from the pretreatment tank 2 flows is formed at one upper portion thereof, and a heating heater 6b. Is installed to heat the waste insulating oil introduced into the inside, and the dechlorination reagent inlet 12 is formed in the upper portion so that the dechlorination reagent metal sodium is inputted by a certain amount, and the inner center portion is vertically stirrer ( 13) is installed to stir and mix the metal sodium and waste insulating oil introduced therein, the lower surface of the reaction tank 10 is formed in the inclined surface 14 to be inclined downward in one direction, so that the initial Unmelted metal sodium is collected to the lower side of one side of the reaction vessel 10 along the inclined surface 14, and the inner side of the lower side of the reaction vessel 10 Auxiliary stirrer 15 is installed vertically so that the metal sodium flowing down the inclined surface 14 is agitated to be melted within a short time, and a reaction tank outlet 16 is formed at the other lower portion of the reactor 10. It is supposed to send the desalted waste insulating oil to the post-treatment tank 21, and a sediment discharge port 20a is formed at one lower side of the inclined surface 14 of the reaction tank 10 to generate the reaction product during the desalination process. It is to send various precipitates including solid sodium chloride and undissolved metal sodium precipitated at the bottom to the separation recovery tank 27, the reaction gas gas outlet 19 is formed at the top of the other side of the reaction tank (10) Treatment of waste insulating oil containing polychlorinated biphenyls, characterized in that for directing the various exhaust gases generated during the desalination reaction to the exhaust gas treatment unit 32. Value. The post-treatment tank inlet of claim 1, wherein the post-treatment tank 21 is a cylindrical casing having a lower portion formed in a cone shape, and one side upper portion of the post-treatment inlet oil into which desalted waste insulating oil from the reaction vessel 10 flows. 22) is formed, and the post treatment tank outlet 23 is formed at the center of the other side, so that the specific gravity is small so that the waste insulating oil floated on the upper side is sent to the treatment oil storage tank 24, and the sediment outlet 20b is located at the bottom of the other side. It is formed to send the sodium chloride and metal sodium and various precipitates precipitated at the bottom due to the large specific gravity to the separation recovery tank 27, the flow rate sensor (8c) on the inside of the other side of the after-treatment tank (21) Is provided, and the post-treatment tank gas outlet 25 is formed at the top of the other side to send various exhaust gases generated in the after-treatment tank 21 to the exhaust gas treatment unit 32, The lower end portion is formed with a drain outlet 26 which is opened and closed by a normal valve, and after the post-treatment, the polychlorinated ratio characterized in that it discharges and processes various residues remaining in the after-treatment tank 21 to the outside. Waste insulating oil treatment device containing phenyl. The post-treatment according to any one of claims 1, 3 and 4, wherein the separation recovery tank 27 is a cylindrical casing and a separation recovery inlet 28 is formed at one upper portion. Various precipitates containing sodium chloride and sodium metal, which are reaction products from the tank 21 and the reaction tank 10, are transported to be introduced into the inside, and a sieve 29 is provided on the inside to solidify the sieve 29. Precipitate containing sodium chloride in the state is to be removed by manure treatment, but the heating means (30a) is installed on the outer peripheral surface of the separate recovery tank (27) while the temperature inside the temperature is maintained at a temperature higher than the melting point of the metal sodium precipitate Metal sodium contained in is re-melted and recovered through the metal sodium recovery port 31 formed at the lower side of the other side, and sent to the dechlorination reagent inlet 12 of the reactor 10 to desalination. Of the polychlorinated biphenyls, characterized in that which is to be reused as a reagent-containing waste insulating oil processing apparatus. According to claim 1, wherein the exhaust gas treatment unit 32 is connected to the plasma heating tube 37 between the exhaust gas treatment unit 33 and the purification filter 34, the desalination treatment through the exhaust gas treatment unit 33 Polychlorinated biphenyls, characterized in that the polychlorinated biphenyls and various harmful gas components are thermally decomposed and burned while passing through the plasma heating tube 37 heated at a temperature of 1000 to 1500 ° C. Waste Insulating Oil Treatment System. 7. The exhaust gas treatment unit 32 according to any one of claims 1 to 4 and 6, wherein the exhaust gas from the pretreatment tank 2, the reaction tank 10, and the aftertreatment tank 21 is collected. The exhaust gas processor 33 is to be introduced into the gas inlet pipe 35, the exhaust gas processor 33 is a liquid sodium fused therein is stored at a predetermined water level and the lower portion of the gas inlet pipe 35 Is located in a state of being locked inside the liquid sodium so that the exhaust gas introduced into the gas inlet pipe 35 passes through the liquid sodium so that the polychlorinated biphenyl contained in the exhaust gas is chemically desalted and discharged. A gas discharge port 36 is formed at an upper portion of the gas processor 33 so that the desalted exhaust gas is discharged through the gas discharge port 36 and sent to the purification filter 34, and the exhaust gas processor 33 is discharged. In the outer circumference of) On means (30b) are here installed polychlorinated biphenyl waste processing apparatus containing the insulating oil, it characterized in that the temperature inside is maintained to be heated to a temperature above the melting point of metallic sodium. 2. The container (4) according to claim 1, wherein the container (4) is contained in and removed from waste insulating oil, and the inside of the container (4) is first washed with compressed air and a dechlorination reagent, and the boiling point of the polychlorinated biphenyl is reduced in a conventional heating furnace (38). The polychlorinated biphenyl component in the solid state, which is heated to a high temperature and sticks to the inner surface of the container 4, is vaporized and sent to the exhaust gas treatment unit 32 for purification. The opening and closing door 39 is provided at one side to input and retrieve the container 4 therein, and the external air inlet 40 equipped with a general blower 41 is provided at one upper portion of the heating furnace 38. And a discharge gas exhaust port 42 is formed at the upper portion of the other side, and the exhaust gas generated while the solid polychlorinated biphenyl component stuck to the inner surface of the container 4 is vaporized from the blower 41. By blowing operation Exhaust gas outlet port 42, the exhaust gas processing polychlorinated biphenyl waste processing apparatus containing the insulating oil, characterized in that which is to be sent to a purification treatment (32) through. Waste insulation oil containing polychlorinated biphenyls from the waste transformer, the condenser, the safety device, and the breaker's container 4 is stored in a predetermined amount in the pretreatment tank 2 and preheated to 50 to 70 ° C. After transferring the preheated waste insulating oil from the reactor to the reaction tank 10 and storing it in a predetermined amount, and heating it at 100-150 ° C. in a state where metal sodium, a dechlorination reagent, was added, the metal sodium was melted and stirred by the stirrer 13. By mixing the polychlorinated biphenyl and the molten sodium chemically reacted and desalted, various precipitates including sodium chloride and undissolved metal sodium, which are precipitated in the lower part of the reaction tank 10, are separated into a recovery tank 27. The desalted waste insulating oil from the reaction tank 10 is sent to the after-treatment tank 21, and the sodium chloride and various precipitates generated during the desalination treatment by cooling at room temperature in a predetermined amount stored therein. The waste insulating oil floated on the upper part while the specific gravity is small while being precipitated is sent to the treatment oil storage tank 24, and the sodium chloride and various precipitates precipitated due to the specific gravity are sent to the separate recovery tank 27, and the post-treatment tank 21 and the reaction tank ( 10) The sodium chloride and various precipitates from 10) are removed by manure treatment with a strainer 29 provided inside the separation recovery tank 27. The internal temperature of the separation recovery tank 27 is heated to a temperature higher than the melting point of the sodium metal. The metal sodium contained in the precipitate is re-melted and returned to the reaction tank 10 to be reused, and the exhaust gas generated in the pretreatment tank 2, the reaction tank 10 and the after-treatment tank 21 is discharged gas. The purification process through the treatment unit 32, the discharge gas is a liquid sodium fused inside is stored at a certain water level and the lower portion of the gas inlet pipe 35 is installed in a state locked in the inside of the liquid sodium The polychlorinated biphenyl contained in the exhaust gas is firstly desalted by chemical reaction with the liquid sodium to pass through the gas processor 33, and the exhaust gas passed through the exhaust gas processor 33 is 1000 to 1500 ° C. While passing through the plasma heating tube 37 heated to a temperature, the polychlorinated biphenyl and various harmful gas components are thermally decomposed and combusted, and discharged to the outside in a filtered state through a purification filter 34. Waste insulating oil treatment method containing polychlorinated biphenyl. 10. The reaction tank 10 according to claim 9, wherein the reaction tank 10 has an inclined surface 14 in which a lower surface thereof is inclined downward toward one side. A side of the lower side of the reaction tank 10 is installed to the secondary stirrer 15 is installed vertically in the lower side of the reaction vessel 10 is characterized in that the molten metal in a rapid time by stirring the metal sodium flowed down along the inclined surface (14) Waste insulating oil treatment method containing polychlorinated biphenyl. 10. The vessel (4) of the waste transformer, condenser, safety device, and circuit breaker according to claim 9, wherein the vessel (4) is first cleaned with compressed air and a dechlorination reagent, and the polychlorination is carried out in a conventional heating furnace (38). Heat treatment to a temperature higher than the boiling point of the biphenyl to 300 ~ 400 ℃ to solidify the polychlorinated biphenyl component stuck to the inner surface of the container 4 is vaporized and the vaporized exhaust gas is the exhaust gas treatment unit ( 32) A method for treating waste insulating oil containing polychlorinated biphenyls, characterized in that for purification.

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