KR100294481B1 - Oil withdrawal device of foam-resin and wast-vinyl class by pyrolsis formula - Google Patents

Abstract

The present invention relates to an oil recovery apparatus for foamed resins and waste vinyls by a pyrolysis method in which a small size, light weight, low operating cost, and a foamed resin and waste vinyls are emulsified safely.

This invention is located above the liquid level of the resin liquid melt | dissolved in the said pyrolysis furnace, and provided with the stirring shaft of the stirring apparatus provided with the some blade located lower than the organic vapor blower outlet, and the liquid surface and the plurality of resin liquid melted The space between the wing and the lower surface of the blade is provided so that it is compact, lightweight, inexpensive and efficient in operation, and prevents environmental pollution. There is an effect of preventing the nitriding, preventing the occurrence of fire in advance, and improving the accumulation and conveyance efficiency of the discarded foamed resin or waste vinyl.

Description

Oil recovery device of foamed resin and waste vinyl by pyrolysis method {OIL WITHDRAWAL DEVICE OF FOAM-RESIN AND WAST-VINYL CLASS BY PYROLSIS FORMULA}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oil recovery apparatus for foamed resins and waste vinyls by pyrolysis, and in particular, small size, light weight, low operating cost, and pyrolysis to safely emulsify foamed resins and waste vinyls (foamed styrol resin). The oil recovery apparatus of foamed resin and waste vinyl by a system is provided.

Generally, foamed resin refers to foamed resin mixed with polyethylene, polypropylene, and polystyrene, and then kneaded, and then swelled by 20 to 80 times by volume to the original polyethylene, polypropylene, or polystyrene. Two or more kinds of foamed resin mixtures in propylene and polystyrene.

After foaming agent is mixed with the polystyrene, the foamed styrene resin kneaded and foamed is used as a cushioning material for packaging electrical and electronic products, used in fish boxes containing fish, or as a tray for food. And the main body of the foamed resin.

The foamed resin and foamed styrol resin are discarded after being used as a buffer material, a fish box, a food tray, etc. In this case, since the volume is large as garbage, the cost of accumulating or conveying the foamed resin or foamed styroline resin that is discarded is greatly increased. There is a problem in that it is difficult to secure a garbage disposal site, and even if a garbage disposal site is secured, it is difficult to bury it as it is.

Moreover, waste disposal facilities are difficult to install in urban areas due to rising land prices and opposition from neighboring residents, and are therefore required to be installed in secluded suburbs far from consumer areas where waste is generated.

As described above, the invention of an apparatus for emulsifying foamed resins and waste vinyls (foamed styrol resins) that are discarded in large quantities in daily life at a low cost, more efficiently and safely, and reused as fuel is difficult to secure a waste disposal site and environmental pollution. It is strongly desired from the standpoint of prevention of energy consumption and reuse of energy resources.

Conventionally, various apparatuses for recovering oil by thermally decomposing plastic waste have been developed and used. For example, the plastic waste is melted or semi-melted by a screw conveying apparatus having a heat mixing kneading apparatus. Japanese Patent Laid-Open Publication No. Hei 9-13045 discloses a device for supplying a dissolution tank installed inside a heating furnace. In this case, the screw conveying device has a mixing kneading function, so that a rigid screw or casing is required. In the conveyance of molten plastic, there was a problem that the maximum required energy was also required. In addition, in the highly rigid screw conveying apparatus using a material having a thick skin thickness, thermal efficiency when heating molten plastic is also lowered and there is a problem in energy efficiency.

In addition, ordinary crushed foamed resins and foamed styrolized resins, which are different from ordinary plastics, can be secured only by a small amount of transportation, even when a large screw diameter conveying device is used with a small specific gravity of about 0.01-0.05 g / cm 3. There was a problem that only small capacity or a huge device can not do. In addition, when heated during transportation, the foamed resin and the foamed styrol resin dissolve to form liquid phases of polyethylene, polypropylene, and polystyrene, but their specific gravity is 0.9-1.0 g / cm 3, compared to the normal crushed foamed or foamed styroline resin. -100 times the number. Therefore, it was difficult to convey a shipment with such a large volume change and a large volume change disturbance while keeping it tightly sealed.

In addition, it is necessary to include a temperature sensor and a heater at the gas outlet of the furnace to heat the atmosphere near the gas outlet according to the temperature measured by the temperature sensor to suppress the rise of bubbles generated in the furnace. It is disclosed in Korean Utility Model Registration No. 3010252, which requires complicated devices and operations and heats up unnecessary energy in order to heat the atmosphere near the gas outlet according to the temperature measured by the temperature sensor. The effect of how much the rise of a bubble is prevented by heating the atmosphere of gas vicinity is unknown.

Therefore, the oil recovery apparatus of the foamed resin and the waste vinyl by the thermal decomposition method according to the present invention, since the organic vapor generated in the device generates harmful odors and is a highly flammable dangerous substance, In view of ensuring safety, the present invention has an airtight structure that prevents organic vapors from leaking out, and realizes an oil recovery apparatus for foamed resin and waste vinyl by a safer pyrolysis method.

The present invention has been made in view of the above circumstances, and a first object thereof is to provide a plurality of vanes on the stirring shaft of the agitation apparatus of the pyrolysis furnace, and to transfer the transport amount at the inlet side of the screw conveying apparatus to the inlet side of the pyrolysis furnace. It is gradually changed to 2.25-10 times by volume ratio, and it makes a function to blow nitrogen gas into a residue box or pyrolysis furnace, and to make a safety valve to keep the pressure of the pyrolysis furnace below a predetermined pressure, By adjusting the weight of the dissolved resin liquid present in the pyrolysis furnace by means of measuring and adjusting the weight to be put into the pyrolysis furnace, and installing a fire protection chamber, it is compact, lightweight, and low in operation cost. It is possible to provide an oil recovery device for foamed resins and waste vinyls by a safe pyrolysis method which is efficient and efficient and does not cause environmental pollution. It's about having it.

The second purpose is to install a plurality of vanes on the stirring shaft of the agitation apparatus of the pyrolysis furnace and press the rise of the bubble layer generated on the liquid surface of the resin liquid dissolved by the force of wind generated by the rotation. This is to prevent deterioration of the axial function and the deterioration of recovered oil by invading the accumulator.

The third purpose is to gradually change the amount of transportation at the inlet side of the screw conveying device to 2.25-10 times in volume ratio compared to the inlet side of the pyrolysis furnace, so that the foaming resin or waste vinyls (foamed styrol resin) to be introduced are Even if the volume change occurs between heating and dissolving the foamed resin or waste vinyl-injected product, it can be transported without causing any gaps in the transported goods, and dissolved in the pyrolysis furnace while maintaining the sealed state. The resin liquid can be carried in continuously.

The fourth purpose is to impart the function of blowing nitrogen gas into the residue box or pyrolysis furnace, and by blowing nitrogen gas into the residue box when the residue is taken out of the pyrolysis furnace, By exchanging air with nitrogen gas or by blowing nitrogen gas into the pyrolysis furnace at start-up, the air in the pyrolysis furnace is exchanged with nitrogen gas. Therefore, it is possible to prevent the occurrence of fire by preventing the mixing of air and organic vapor.

The fifth object is to prevent breakdown due to an abnormal pressure rise in the pyrolysis furnace by making a safety valve that maintains the pressure in the pyrolysis furnace below a predetermined pressure.

The sixth purpose is to determine the input weight (A) of the foamed resin or waste vinyl (foamed styrol resin) and the discharge weight (B), and to adjust the input weight (A) according to the discharge weight (B). By maintaining the amount of resin (Q) dissolved therein at a predetermined value, a suitable bubble space is ensured, and the foaming function penetrates into the shaft of the shaft and the deterioration of the shaft function and the deterioration of recovered oil are recovered. To prevent it.

The seventh object is to enclose a pyrolysis furnace, a residue box, etc. in a fire prevention chamber to ventilate the air in the fire prevention chamber, and to install a temperature sensor or a fire damper so that the air temperature in the fire prevention chamber and the temperature of the air flowing through the fire prevention damper are predetermined temperatures. In case of abnormality, it is designed to close the fire damper and emergency stop the device that injects nitrogen gas into the fire chamber. When the gas detector is made in the fire chamber again and the flammable gas is detected, the device is emergency stopped and the pyrolysis is higher. The present invention provides an oil recovery apparatus for foamed resins and waste vinyls.

In order to achieve the above object, the present invention provides a screw conveying apparatus for conveying to a pyrolysis furnace while heating and dissolving a foamed resin, which is a granular material, by heating and crushing it with a shredder or a reduction vessel, and heating while receiving and stirring the dissolved resin liquid In the emulsification apparatus of foamed resin provided with the pyrolysis furnace, the condenser which liquefies the organic vapor which arises by the thermal decomposition of the melted resin liquid, and the oil / water separator which separates oil and water, the resin liquid melt | dissolved in the said pyrolysis furnace A stirring shaft of a stirring device having a plurality of blades is provided at a position above the liquid level of the liquid extract and located below the organic vapor outlet, and a bubble space is provided between the liquid surface of the dissolved resin liquid and the plurality of wing bottom surfaces. It is to provide an oil recovery apparatus of the foamed resin and waste vinyl by the pyrolysis method.

In addition, the present invention is provided with a heater on the outer peripheral surface of the casing of the screw conveying apparatus for heating and dissolving the foamed resin or waste vinyls and dissolving the foamed resin or waste vinyl, the conveying amount at the inlet side is 2.25- in volume ratio compared to the inlet side of the pyrolysis furnace. The present invention provides an oil recovery apparatus for foamed resins and waste vinyls by a pyrolysis method in which the thickness of the screw shaft or the pitch of the screw is gradually changed to 10 times or the thickness of the screw shaft and the pitch of the screw are gradually changed. The apparent specific gravity of the resin or the foamed styrol resin is extremely small, such as 0.01-0.05 g / cm 2, so that the transportation efficiency is poor. However, the mixture of the foamed resin or the powdered foamed resin of the foamed styrene resin is 0.1- in terms of the specific gravity. It is 0.4 g / cm <2>, and the specific gravity of the liquid which melt | dissolved polyethylene, polypropylene, and polystyrene is 0.9-1.0 g / cm <2>. Therefore, if it is possible to process in the volume ratio range when the treated object is processed into a container with foamed resin or waste vinyl (foamed styrol resin), the center range of the apparent specific gravity of the mixed body of the foamed resin or foamed styrene resin is 0.2-. Since it is 0.3g / cm <2>, the conveyance amount in the inlet side is 3-5 times by volume ratio compared with the inlet side of a pyrolysis furnace, and it is good at the point which raises a transportation efficiency.

In addition, the present invention forms a residue outlet at the bottom of the pyrolysis furnace, while the residue is taken out from the pyrolysis furnace to be recovered to the residue box, and the residue is connected by connecting nitrogen gas piping to the pyrolysis furnace and the residue box. When withdrawing from the pyrolysis furnace and then starting again, when there is a risk of air and organic vapor contact mixing, open the nitrogen valve to blow nitrogen gas into the residue box or the pyrolysis furnace to The present invention provides an oil recovery apparatus for foamed resin and waste vinyl by a pyrolysis method for exchanging air and nitrogen gas in a water box or a corresponding pyrolysis furnace.

Furthermore, in the present invention, when the internal pressure of the pyrolysis furnace is increased to 0-0.2Kg / cm 2 and the internal pressure of the pyrolysis furnace is increased to 0.3Kg / cm 2, the safety valve is operated to open to the atmosphere, thereby increasing the internal pressure of the pyrolysis furnace. The present invention provides an oil recovery apparatus for foamed resin and waste vinyl by pyrolysis.

In addition, the present invention is to install the input hopper and the metering hopper on the top of the inlet of the screw conveying device, the gate is installed between the input hopper and the metering hopper, the load cell is installed in the metering hopper, the amount of the input hopper (E ) And the relationship between the discharge (B) measured by the flow meter and the amount of dissolved resin (Q) present in the pyrolysis furnace, with a flowmeter installed in the pipe connecting the condenser to the oil / water separator. Q = μ x (AB By setting the input amount (A) to the target value to obtain the required time (T) for conveying the input amount (E) to control the rotation speed of the screw, while the weight of the dissolved resin present in the pyrolysis furnace to a predetermined value It is an object of the present invention to provide an oil recovery apparatus for foamed resin and waste vinyl by a pyrolysis method to be maintained.

In the present invention, after the pyrolysis furnace or the residue box is wrapped in the fire chamber, an exhaust device including a suction port, a fire damper, a duct, and a blower is provided, and the temperature sensor is directed toward a plurality of nitrogen gas pipes in the fire chamber. If the air flowing in the fire damper reaches a predetermined temperature, the fire damper automatically closes when the air flowing in the fire damper reaches a predetermined temperature, and when the temperature sensor teaches a predetermined temperature or more, the corresponding fire damper closes. If it does, open the nitrogen valve and blow nitrogen gas into the fire prevention chamber to make the device emergency stop, and install the gas detector in the fire protection chamber to make the emergency stop even when detecting flammable gas. To provide an oil recovery apparatus of.

1 is an overall configuration diagram showing an embodiment of the device according to the present invention.

* Explanation of symbols on the main parts of the drawings *

1 ... screw conveyer 2 ... casing

3,20 ... heater 4 ... screw shaft

5 ... screw 6 ... slot

7 ... Input hopper 11 ... Pyrolysis furnace

12 ... melted resin solution (dissolved waste vinyl or styrol resin solution)

13 ... liquid level 14 ... agitator

15 ... agitator shaft 19 ... vane

25 ... inlet 26 ... organic vapor outlet

28 ... residue outlet 29 ... residue valve

30 ... gunspace 31 ... ceiling space

35 ... Thruster 40 ... Oil-water separator

41 ... pipe 45 ... residue box

47 ... Residue 50 50 ... Nitrogen Bomb

51 ... nitrogen gas piping 52 ... nitrogen valves

55 ... safety valve 56 ... flare stocker

60 ... Air transport 70 ... Fire protection chamber

71 ... inlet 72 ... fire damper

73 ... Duct 74 ... Blower

77 ... exhaust 80 ... flow meter

81 ... Cyclone 82 ... Weighing Hopper

83,84 ... gate 85 ... load cell

Next, embodiments of the present invention will be described in detail with reference to the drawings.

Figure 1 shows an embodiment of the apparatus according to the present invention, the oil recovery apparatus of the foamed resin and waste vinyl by this pyrolysis method is a screw conveying apparatus (1), a pyrolysis furnace (11), a condenser (35) ), And an oil / water separator 40 and a fire chamber 70.

The pyrolysis furnace 11 is a container including a disk-shaped ceiling 21, a cylindrical furnace wall 24, and a conical base plate 28. In addition, a heater 20 is installed on the outer surface of the furnace wall 24 or the bottom plate 27 so as to heat the dissolved resin liquid 12 accommodated in the pyrolysis furnace 11, and the residue ejection opening ( 28, while a residual valve 29 is interposed therebetween and connected to the residue port 47.

The stirring shaft 15 is vertically arranged in the center of the pyrolysis furnace 11, and the stirring shaft 15 is rotatably installed in the horizontal direction by a driving mechanism (not shown). The stirring plate 17 is installed at the lower end of the stirring shaft 15, the stirring plate 16 is installed at the upper portion of the stirring plate 17, the stirring plate 16, the furnace wall 24, and the bottom surface 27. It is a means for sliding the tip end of the scraper 18 against the inner surface of the furnace wall 24 and the bottom surface 27 via the scraper 18 between the inner surface and the inner surface.

The liquid level of the resin liquid 12 which was located above the stirring plate 16 and installed in the pyrolysis furnace 11 by having a plurality of vanes 19 at a lower position than the organic vapor outlet 26 of the furnace wall 24. The bubble space 30 is suitably created between 13 and the lower surface of the said some wing 19, and it blows toward the liquid surface 13 of the resin liquid 12 melt | dissolved from the top at the time of stirring.

In the present embodiment, the melted resin liquid 12 is approximately 1/3 of the dedicated volume of the pyrolysis furnace 11, and the upper surface 16a of the stirring plate 16 is dedicated to the dedicated volume of the pyrolysis furnace 11. The plurality of blades 19 have almost the same volume as the ceiling space 31 and the bubble space 30 existing between the upper surface and the ceiling 21 at the positions substantially divided into two.

The furnace wall 24 of the pyrolysis furnace 11 is provided with an inlet 25 or an organic vapor outlet 26, and a ceiling 21 is provided with a nitrogen supply port 22 or a tool (runout) 23, respectively. The screw conveyer 1 and the pipe 33 are erected between the shaft 35, the nitrogen gas pipe 51, and the nitrogen valve 52 to erect the cylinder 50, the pipe 57 and the safety valve 55. Connect to the flare stocker (56). The ceiling 21 is inclined a little with respect to the horizontal so that the oil adhered to the inner surface of the ceiling flows through the organic vapor outlet 26, and at the same time, the oil vapor dropped through the lower surface 32 of the organic vapor outlet 26 is dropped. The discharge port 26 is recovered.

The screw conveying apparatus 1 is disposed almost horizontally with the screw shaft 4 in the casing 2, and the screw shaft 4 is driven by a drive mechanism (not shown) to be rotated in the vertical direction. The speed is variable within a predetermined range, while driving at a randomly instructed rotational speed within that range. A heater 3 is provided on the outer circumference of the casing 2 to heat the foamed resin or waste vinyl (foamed styrol resin) during conveyance. The inlet port 25 is provided on the pyrolysis furnace 11 side of the casing, and the inlet port 6 is provided on the opposite side of the casing, and the screw port 5 is provided on the outer periphery of the screw shaft 4 to the inlet port 6. The injected foamed resin and waste vinyls (foamed styrol resin) are conveyed toward the delivery port 25.

The thickness of the screw shaft 4 is gradually thickened from the inlet 6 side to the inlet 25 side, and the pitch of the screw 5 is gradually reduced from the inlet 6 side to the inlet 25 side. The transport volume at the inlet (6) side is 2.25-10 times in volume ratio relative to the transport volume at the inlet (25) side. In addition, it is preferable that the transportation amount on the inlet 6 side is 3-5 times the volume ratio relative to the transportation volume on the inlet 25 side in terms of transportation ratio.

While the input hopper 7 is installed on the top of the inlet 6, the metering hopper 82 is installed on the upper part of the input hopper 7, and the cyclone 81 is installed on the upper part of the metering hopper 82. The gate 83 is provided between the injection hopper 7 and the metering hopper 82, and the gate 84 is provided between the metering hopper 82 and the cyclone 81, respectively. 84) to open and close automatically. In addition, the weighing hopper 82 is provided with a load cell 85.

The cyclone 81 is connected to the pipe 63 of the air transport device 60, which is provided with a supply screw 62, a rotary valve 61, a blower 64, and a pipe 63, and foamed resin or waste vinyl. (Foamed styrol resin) is introduced into the cyclone 81. In addition, the screw conveying apparatus 1 is slightly inclined with respect to the horizontal so that the inlet 6 side is set a little higher to prevent the dissolved resin from flowing to the inlet 6 side.

The organic vapor outlet 26 of the pyrolysis furnace 11 stands between the pipes 33 and is connected to the inlet 34 of the condenser 35, and the condenser 35 has a drain hole at the water supply port 36. The pipe pipe 38, which is sequentially stacked, is connected over 37, so that the water supplied from the water supply port 36 flows through the pipe pipe 38 and flows out from the outlet 37.

The outlet 39 of the condenser 35 is mounted between the pipes 41 and connected to the oil / water separator 40, and a flow meter 80 is provided in the middle of the pipes 41. In the oil / water separator 40, oil and water are separated by a difference in specific gravity, and only oil is recovered to the product oil tank 43 through the production oil pipe 42. A residue ejection opening 28 is formed in the lower portion of the pyrolysis furnace 11, and a residue valve 29 and a residue opening 47 are interposed between the residue box 45 and connected to the residue box 45 to take out the pyrolysis furnace 11. One residue is recovered to the interior 46 of the residue box 45.

The pyrolysis furnace 11 and the residue box 45 are surrounded by a fire protection chamber 70 to an exhaust device 77 including a suction port 71, a fire damper 72, a duct 73, and a blower 74. As a result, the air in the fire protection chamber 70 is discharged. The fire protection chamber 70 is provided with a temperature sensor or a gas detector, and the fire protection damper 72 automatically closes the fire damper 72 when the temperature of the flowing air reaches a predetermined temperature or more. In addition, a nitrogen cylinder 50 is installed to interpose the pipe 51 and the nitrogen valve 52 in the nitrogen cylinder 50 so that the nitrogen supply port 22 and the residue box 45 of the pyrolysis furnace 11 are installed. It is connected to the nitrogen supply port 53 and the nitrogen supply port 69 of the fire protection chamber 70.

The internal pressure of the pyrolysis furnace 11 is zero by heating the temperature of the dissolved resin liquid 12 of the pyrolysis furnace 11 to 350-450 ° C. and maintaining the temperature of the ceiling space 31 at 300-400 ° C. When the internal pressure of the pyrolysis furnace 11 rises to 0.3Kg / cm 2 and is controlled at -0.2Kg / cm 2, the internal pressure of the pyrolysis furnace 11 is prevented by operating the safety valve 55 and releasing to the atmosphere. Done. The organic vapor released from the safety valve 55 is guided to the flare stocker 56 which is set up between the pipes 57 and combusted with combustion of propane gas.

One embodiment of the present invention constituted as described above is pre-crushed or reduced by the use of a container to form a sieve, foamed resin or waste vinyl (foamed styrol resin) is transported to the cyclone 81 by the air transport device 60 On the other hand, it falls from the cyclone 81 and accumulates in the lower part of the cyclone 81.

In advance, the gates 83 and 84 are closed and only the gate 84 is opened when the inside of the input hopper 7 is empty. Then, the foamed resin or waste vinyl (foamed styrol resin) of the cyclone 81 falls and enters the weighing hopper 82. After that, the gate 84 is closed, and the weight of the foamed resin or waste vinyl (foamed styrol resin) in the metering hopper 82 is measured together with the metering hopper 82 in the load cell 85. When the weight of the weighing hopper 82 is subtracted from the measured weight, it is possible to determine the injection amount E into the injection hopper 7.

Thereafter, only the gate 83 is opened, and the foamed resin or waste vinyl (foamed styrol resin) in the metering hopper 82 is supplied to the input hopper 7. The foamed resin or waste vinyl (foamed styrol resin) that has entered the feed hopper 7 passes through the feed opening 6 and is supplied to the screw conveying apparatus 1.

Since the foamed resin or waste vinyl (foamed styrol resin) which has entered the screw conveying apparatus 1 is heated by the heater 3 while being conveyed by the screw 5, it gradually melts into a solution and then, It is carried in to the pyrolysis furnace 11 from the delivery opening 25. A relational expression between the amount of dissolved resin (Q) and the amount of discharge (B) present in the input amount (A) and the pyrolysis furnace 11 is obtained by calculating the input amount (A), where A = (Q / μ) -B. Therefore, at the time of starting the device, the input amount A is controlled until Q becomes a predetermined target value, but after Q becomes a predetermined value and normal operation is performed, the input amount a (a It is good to match = E / T) to the emission b per unit time.

In this case, the rotational speed for transporting the input amount E into the injection hopper 7 at a predetermined time T is controlled so that the rotational speed of the screw 5 becomes a transport amount per unit time. In addition, "μ" differs depending on the capacity balance of the screw conveying apparatus 1, the pyrolysis furnace 11, the condenser 35, etc. which exist in the apparatus, and the range of (micro | micron | 0.9-0.98) is economical, The experimental value of is μ = 0.95.

The melted resin liquid 12 brought into the pyrolysis furnace 11 is heated by the heater 20 while being stirred by the rotation of the stirring plate 17 or the stirring plate 16 of the stirring device 14 to receive 350-450. It is held at 占 폚 and is thermally decomposed to vaporize. At this time, a large amount of foam is generated, but the foam layer is stopped in the bubble space 30 by the force of the wind generated by the rotation of the blades 19 installed on the stirring shaft 15 of the stirring device 14.

The organic vapor decomposed and vaporized in the pyrolysis furnace 11 reaches the condenser 35 through the pipe 33 at the organic vapor outlet 26. At this time, since the condenser 35 is cooled by water flowing from the water supply port 36 to the drain hole 37 through the pipe pipe 38, the organic vapor is liquefied.

The organic liquid liquefied in the condenser 35 flows into the oil / water separator 40 through the pipe 41 at the outlet 38. The flow rate of the organic liquid liquefied by the flowmeter 80 is measured. In the oil / water separator 4, the oil and water have different specific gravity, and both are separated, and the oil is recovered to the production oil tank 43 through the production oil pipe 42. On the other hand, moisture is discharged through the valve 44.

In the pyrolysis furnace 11, the non-decomposed component contained in the dissolved resin liquid 12 is generated as a residue of solids, but when this becomes a large amount, the residue is taken out because it hinders the stirring performance of the stirring device 14. You need to do it. When taking out the residue, the residue valve 29 is opened to rotate the stirring device 14, and the residue remains due to the inclination of the bottom plate 27 and the rotation of the stirring plate 16 and the stirring plate 17. It falls into the interior 46 of the residue box 45 through the water outlet 28, the residue valve 29, and the residue opening 47.

When the residue is taken out, when the residue is taken out and then restarted, the nitrogen valve 52 is opened to inhale nitrogen gas into the residue box 45 or the pyrolysis furnace 11, and the residue box 45 is opened. The occurrence of fire is prevented by extracting air inside the pyrolysis furnace 11 and replacing it with nitrogen gas. In addition, the extracted air is guided to the flare stocker 56 to combust along with the combustion of propane gas.

In the present embodiment, the foamed resin and the waste vinyl (foamed styrol resin), which are granulated by heat-treating by shredding or reduction, are transported to the cyclone 81 by the air transportation device 60. The present invention is not limited thereto, and may be performed in various ways, such as by attaching an import (take-in) hopper instead of the cyclone 81 and putting the hopper directly into the import hopper.

In addition, an embodiment in which the organic vapor released from the safety valve 55 and the like are combusted by the flare stopper 56 has been described, but this is the organic vapor or residue box 45 and the pyrolysis furnace 11 released from the safety valve 55. Treatment of air extracted from can be performed by various methods such as filtration by a wet dust collector or a filter or adsorption by activated carbon, but is not limited to this embodiment.

As mentioned above, according to this invention, the some blade 19 is provided in the stirring shaft 15 of the stirring apparatus 14 of the pyrolysis furnace 11, and is located in the inlet 6 side of the screw conveying apparatus 1. By gradually changing the transport amount to be 2.25-10 times in volume ratio relative to the inlet 25 side of the pyrolysis furnace 11, and injecting nitrogen gas into the residue box 45 or the pyrolysis furnace 11, By making the safety valve 55 which maintains the pressure of the pyrolysis furnace 11 below a predetermined pressure, there is an effect that it is compact, light in weight, inexpensive to operate and efficient, and also prevents environmental pollution.

Moreover, the liquid surface 13 of the resin liquid 12 melt | dissolved by installing the some blade 19 in the stirring shaft 15 of the stirring apparatus 14 of the pyrolysis furnace 11, and the wind force generate | occur | produced by the rotation. In order to suppress the rise of the foam layer generated in the above), it is possible to prevent the invasion of the undecomposed solution into the shaft 35, and to prevent the shaft 35 from degrading and reducing the recovered oil fraction. .

In addition, the amount of foam on the inlet 6 side of the screw conveying apparatus 1 is gradually changed to be 2.25-10 times in volume ratio compared with the side of the inlet 25 of the pyrolysis furnace 11, and the foamed resin or waste vinyl to be added It is limited to the particle of waste vinyls (foamed styrol resin) which heat-treated (foamed styrol resin) by the demagnetizer, and conveys without making a gap in a shipment even if a volume change arises while conveying, heating and dissolving. It is also possible to carry out the resin liquid melt | dissolved in the pyrolysis furnace 11 continuously, maintaining a closed state.

Further, nitrogen gas is blown into the residue box 45 or the pyrolysis furnace 11 so that the nitrogen gas is supplied to the residue box 45 when the residue is taken out from the pyrolysis furnace 11 and then started. Air is extracted by blowing into the pyrolysis furnace 11 and exchanged with nitrogen gas, thereby preventing the occurrence of fire.

Moreover, by making the safety valve 55 which keeps the pressure of the pyrolysis furnace 11 below predetermined pressure, it becomes possible to prevent the destruction by the abnormal rise of the pressure of the pyrolysis furnace 11, and ensures safety. There is also an effect that can be done. In the case where the injected foamed resin or waste vinyl (foamed styrol resin) is limited to an injection body of waste vinyl (foamed styrol resin) heated and reduced by a container, the accumulation and conveyance effect of the waste waste vinyl (foamed styrol resin) can be improved. If only the capacitor is installed near the consumer of electrical and electronic products or fishery products in which a large amount of foamed resin or waste vinyl (foamed styroline resin) to be discarded is discharged, Only the foamed resin and waste vinyls (foamed styrol resin) which are heat-treated can be transported, and there is an effect of improving the accumulation and conveyance efficiency of the discarded foamed resin and waste vinyls (foamed styrol resin).

In addition, it is possible to process the foamed resin containing polyethylene, polypropylene, and polystyrene without limiting the object to the foamed roll, and to deal with the process as compared with the case of using waste vinyl (foamed styrol resin) powder. The present invention is not limited, and only waste vinyls (foamed styrol resins) need not be sorted, so that the work process is simplified and the costs required for sorting are also unnecessary.

Further, the pyrolysis furnace 11, the residue box 45, and the like are surrounded by the fire protection chamber 70, and the air in the fire protection chamber 70 is vented by the exhaust device 71, so that the fire protection damper 72 and the temperature sensor 75 are provided. When nitrogen gas is blown into the fire protection chamber 70 by the operation of), the device is emergency stopped by the detection of the gas detector 76, so that the safety of the entire device is improved and the fire protection chamber 70 is not present. When the residue was taken out from the pyrolysis furnace 11, it was necessary to blow nitrogen gas into the pyrolysis furnace 11 or the residue box 45, and then wait for the temperature in the pyrolysis furnace 11 to cool down to room temperature, Since the safety of the chamber 70 is improved, the residue is taken out from the pyrolysis furnace 11 to the residue box 45 immediately after blowing nitrogen gas without waiting for the temperature in the pyrolysis furnace 11 to decrease. It also has the effect that it becomes possible.

Claims (12)

A screw conveying apparatus for conveying to a pyrolysis furnace while heating and dissolving the foamed resin which is a granular body by heating and dissolving with a crusher or a reduction vessel, a pyrolysis furnace for receiving and stirring the dissolved resin liquid and heating it, and for thermal decomposition of the dissolved resin liquid. In the emulsification device of the foamed resin comprising a condenser for liquefying the organic vapor generated by the oil and a water oil separator for separating oil and water, A stirring shaft of a stirring device having a plurality of blades is disposed above the liquid level of the resin liquid dissolved in the pyrolysis furnace and positioned below the organic vapor outlet, and the liquid surface of the dissolved resin liquid and the plurality of wing lower surfaces An oil recovery apparatus of the foamed resin by the pyrolysis method, characterized in that the bubble space is provided between the and. A screw conveying apparatus for heating and dissolving waste vinyls into granules by crushing or using a shredder and dissolving them, and a pyrolysis furnace for receiving and stirring the dissolved polystyrene liquid and heating the dissolved polystyrene liquid. In the emulsification apparatus of the waste vinyls provided with the condenser which liquefies the organic vapor generate | occur | produced by decomposition, and the oil-water separator which separates oil and water, Between the liquid surface of the polystyrene liquid and the lower surface of the plurality of blades, which are located above the liquid level of the polystyrene liquid dissolved in the pyrolysis furnace, and are provided with a stirring shaft of a stirring device having a plurality of wings below the organic vapor outlet. An oil recovery apparatus for waste vinyls by a pyrolysis method, characterized by having an interstitial space provided therebetween. The heater is provided on the casing outer circumferential surface of the screw conveying apparatus for conveying the foamed resin to the pyrolysis furnace while heating and dissolving the foamed resin, and the conveying amount at the inlet side is 2.25-10 times larger than the inlet side of the pyrolysis furnace. The oil recovery apparatus of the foamed resin by the thermal decomposition method characterized by gradually changing the thickness of a screw shaft or the pitch of a screw, or gradually changing the thickness of a screw shaft and the pitch of a screw. 3. The method of claim 2, wherein a heater is provided on the periphery of the casing of the screw conveying apparatus for conveying the waste vinyls to the pyrolysis furnace while heating and dissolving the waste vinyls, and the volume is 2.25-10 in volume ratio compared to the inlet side of the pyrolysis furnace of the conveying amount on the inlet side. An oil recovery apparatus for waste vinyls by the pyrolysis method, wherein the thickness of the screw shaft or the pitch of the screw is gradually changed to double, or the thickness of the screw and the pitch of the screw are gradually changed. 4. The process according to claim 1 or 3, wherein a pyrolysis furnace is provided with a residue outlet at the bottom, while the residue is taken out of the pyrolysis furnace and recovered in a residue box, and the nitrogen gas piping is connected to the pyrolysis furnace and the residue box. When connected and withdrawing residue from the pyrolysis furnace and then restarted, when there is a risk of air and organic vapor contact and mixing, open the nitrogen valve to blow nitrogen gas into the residue box or the pyrolysis furnace. A device for recovering oil of a foamed resin according to the pyrolysis method, characterized in that air and nitrogen gas are exchanged in the residue box or the pyrolysis furnace. 5. The method of claim 2 or 4, wherein a pyrolysis furnace is provided with a residue outlet at the bottom, while the residue is taken out of the pyrolysis furnace and recovered in a residue box, and the nitrogen gas piping is connected to the pyrolysis furnace and the residue box. When the residue is connected to take the residue out of the pyrolysis furnace and then restarted, when there is a risk of contact and mixing of air and organic vapors, the nitrogen valve is opened to provide nitrogen gas to the residue box or the pyrolysis furnace. An oil recovery apparatus for waste vinyls by pyrolysis, characterized in that for blowing air and nitrogen gas into the residue box or the pyrolysis furnace. The method of claim 1, 3 or 5, wherein the internal pressure of the pyrolysis furnace is set to 0-0.2Kg / cm 2, and when the internal pressure of the pyrolysis furnace rises to 0.3Kg / cm 2, the safety valve is operated to open to the atmosphere. The oil recovery apparatus of the foamed resin by the pyrolysis method characterized in that to prevent the increase in the internal pressure of the pyrolysis furnace. The method of claim 2, 4 or 6, wherein the internal pressure of the pyrolysis furnace is set to 0-0.2Kg / cm 2, and when the internal pressure of the pyrolysis furnace rises to 0.3Kg / cm 2, the safety valve is operated to open to the atmosphere. The oil recovery apparatus of the waste vinyls by the pyrolysis method characterized by preventing the internal pressure of the pyrolysis furnace from rising. 8. The metering hopper according to claim 1, 3, 5 or 7, wherein an input hopper and a metering hopper are provided at an upper part of the inlet of the screw conveying device, and a gate is provided between the inlet hopper and the metering hopper. A load cell is installed in the tank, and a flow meter is installed in the input hopper, a pipe connected to the oil separator from the condenser, and the discharged water measured by the flow meter is dissolved in the pyrolysis furnace. The rotational speed of the screw is controlled by calculating the required time (T) for conveying the input amount (E) by setting the input amount (A) to the target value according to the relationship Q = μ x (AB) of the resin amount (Q). An apparatus for recovering oil of a foamed resin by a pyrolysis method, wherein the weight of dissolved resin present in the furnace is maintained at a predetermined value. 9. The metering hopper according to claim 2, 4, 6 or 8, wherein an input hopper and a metering hopper are provided at an upper part of the inlet of the screw conveying device, and a gate is provided between the inlet hopper and the metering hopper. A load cell is installed in the tank, and a flow meter is installed in the input hopper, a pipe connected to the oil separator from the condenser, and the discharged water measured by the flow meter is dissolved in the pyrolysis furnace. The rotational speed of the screw is controlled by calculating the required time (T) for conveying the input amount (E) by setting the input amount (A) to the target value according to the relationship Q = μ x (AB) of the resin amount (Q). An oil recovery apparatus for waste vinyls by the pyrolysis method, wherein the weight of the dissolved resin present in the furnace is maintained at a predetermined value. 10. The exhaust system according to claim 1, 3, 5, 7, or 9, wherein after the pyrolysis furnace or the residue box is wrapped in the fire chamber, an exhaust device having a suction port, a fire damper, a duct, and a blower is provided. On the other hand, a temperature sensor is installed toward a plurality of nitrogen gas pipes in the fire protection chamber, and the fire damper is equipped with a temperature fuse to automatically close the fire damper when the air flowing in the fire damper reaches a predetermined temperature. When the sensor teaches more than a certain temperature, and when the fire damper is closed, open the nitrogen valve to blow nitrogen gas into the fire chamber to emergency stop the device, and install a gas detector inside the fire chamber. An oil recovery apparatus for a foamed resin by a pyrolysis method, characterized in that emergency stop occurs even when gas is detected. The exhaust system according to claim 2, 4, 6, 8, or 10, wherein after the pyrolysis furnace or the residue box is enclosed in the fire chamber, an exhaust device having a suction port, a fire damper, a duct, and a blower is installed. On the other hand, a temperature sensor is installed toward a plurality of nitrogen gas pipes in the fire protection chamber, and the fire damper is equipped with a temperature fuse to automatically close the fire damper when the air flowing in the fire damper reaches a predetermined temperature. When the temperature sensor teaches more than a certain temperature, and when the fire damper is closed, open the nitrogen valve to blow nitrogen gas into the fire chamber to emergency stop the device, and install a gas detector inside the fire chamber. An oil recovery apparatus for waste vinyls by pyrolysis, characterized in that emergency stop occurs even when flammable gas is detected.