JP3819634B2 - Pyrolysis residue cooling transfer equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is used in a carbonization pyrolysis melting and combustion apparatus for waste such as municipal waste, and pyrolysis gas and pyrolysis residue generated in a pyrolysis drum that pyrolyzes the waste is pyrolyzed gas. Between the separator for separating the pyrolysis residue and the separation device for sorting the separated pyrolysis residue, and cooling the pyrolysis residue discharged from the separator in a low oxygen atmosphere. It is related with the improvement of the pyrolysis residue cooling conveyance equipment made to convey to a sorter.
[0002]
[Prior art]
FIG. 2 shows a schematic system diagram of a conventional pyrolysis residue cooling and transporting facility used in a dry distillation pyrolysis melting and combustion apparatus for waste, and the pyrolysis residue cooling and transporting facility is disposed on the outlet side of the pyrolysis drum 1. Between the separator 2 that is provided and separates the pyrolysis gas G and the pyrolysis residue D discharged from the pyrolysis drum 1 and the sorting device 3 that sorts the separated pyrolysis residue D, the first vibration The feeder 4, the coarse vibrating screen 5, the cooling conveyor 6, the bucket conveyor 7 and the second vibrating feeder 8 are sequentially arranged in series.
In FIG. 2, 12 is a double damper, 13 is an open / close gate, 14 is a bulk storage container, 19 is a grinder, 20 is a carbon residue conveyor, 21 is a carbon residue silo, and 22 is a carbon residue. A conduit 23 is a carbon residue blower.
[0003]
Thus, the waste supplied to the pyrolysis drum 1 is heated to a temperature of 300 ° C. to 600 ° C. under the shut-off of air by a heated gas from a hot air generating furnace (not shown). It is decomposed into gas G and thermal decomposition residue D. This pyrolysis gas G contains moisture, CO, CO ₂ , H ₂ The pyrolysis residue D is a mixture of carbon residue, iron, aluminum, glass, stone, concrete, and the like.
[0004]
The pyrolysis gas G and pyrolysis residue D generated in the pyrolysis drum 1 are introduced into a separator 2 adjacent to the pyrolysis drum 1, where it is separated into pyrolysis gas G and pyrolysis residue D by gravity. Is done.
[0005]
The pyrolysis gas G is directly introduced into a melt combustion apparatus (not shown) through a pyrolysis gas conduit (not shown), where organic substances contained in the gas are completely burned and decomposed by high-temperature combustion. Is done. The combustion exhaust gas generated in the melt combustion apparatus continues to flow into a waste heat boiler (not shown) and is recovered for heat, and then cleans through a dust collector, exhaust gas purification device, an induction fan (all not shown), etc. It is discharged as a gas into the atmosphere.
[0006]
On the other hand, the pyrolysis residue D is dropped and discharged from the separator 2 via the double damper 12 into the first vibration feeder 4 and then supplied from the first vibration feeder 4 into the coarse vibration screen 5. The double damper 12 provided on the outlet side of the pyrolysis residue D of the separator 2 is for sealing between the separator 2 and the first vibration feeder 4. The outlet of the pyrolysis residue D of the separator 2 is sealed by the double damper 12 when the low-temperature gas in the cooling conveyor 6 is sucked into the separator 2 or the pyrolysis gas conduit. This is because the tar contained in the solidified product may solidify and block the pyrolysis gas conduit.
[0007]
The pyrolysis residue D introduced into the coarse vibrating screen 5 is subjected to a vibrating action on the screen (not shown), and the coarse residue (metal wire or relatively large debris contained in the pyrolysis residue D). Sort etc.). That is, the relatively fine pyrolysis residue D on the screen is dropped and discharged into the cooling conveyor 6 through the screen eyes due to the vibrating action of the screen. The coarse material remaining on the screen is dropped and discharged from the screen into the coarse material storage container 14.
[0008]
The fine pyrolysis residue D discharged into the cooling conveyor 6 was indirectly cooled by the cooling water W in a low oxygen atmosphere and lowered from a temperature of about 450 ° C. to a temperature of about 80 ° C. After that, it is sent to the sorting device 3 by the bucket conveyor 7 and the second vibration feeder 8. The reason why the pyrolysis residue D is cooled in a low-oxygen atmosphere in the cooling conveyor 6 is to prevent combustion, explosion, etc. of the pyrolysis residue D at a high temperature (300 ° C. to 500 ° C.). Therefore, an inert gas G ′ such as nitrogen gas is supplied into the cooling conveyor 6 from the inert gas supply pipe 15, and the inside of the cooling conveyor 6 is maintained in a low oxygen atmosphere by the inert gas G ′. .
[0009]
The pyrolysis residue D sent to the sorting device 3 is converted into iron, aluminum, rubble (stone, concrete pieces, glass pieces, etc.) and carbon residue D ′ by a magnetic separator, a vibrating screen and an aluminum sorter. Sorted.
[0010]
Iron, aluminum and rubble sorted by the sorting device 3 are respectively stored in a bunker (not shown), and a relatively large carbon residue D ′ is pulverized to about 1 mm or less by a pulverizer 19 and then used for carbon residue. After being transported to the carbon residue silo 21 by the conveyor 20 and once stored in the carbon residue silo 21, it is pneumatically transported by the carbon residue conduit 22 and the carbon residue blower 23 and sent to the melting combustion apparatus, It is melted and combusted with the pyrolysis gas G to form molten slag.
[0011]
[Problems to be solved by the invention]
By the way, in the above-described pyrolysis residue cooling and transporting equipment, a coarse meter storage container 14 connected to a coarse material discharge port of the coarse material vibration screen 5 is provided with a weight meter or a level meter (both not shown), When the bulk material stored in the storage container 14 reaches a certain weight or level, an operator manually replaces the bulk material storage container 14 and takes out the bulk material from the removed bulk material storage container 14. .
[0012]
However, in the coarse vibration screen 5 of the pyrolysis residue cooling and transporting facility, the coarse product in the pyrolysis residue D cannot be completely screened, and the fine pyrolysis residue D and the coarse product are coarse. It was discharged together in the material storage container 14 or was discharged to the coarse material storage container 14 in a state where the fine pyrolysis residue D adhered to the coarse material. In addition, fine pyrolysis residues floating in the atmospheric gas sometimes settle and accumulate in the coarse substance storage container 14.
As a result, when a coarse product is taken out from the coarse product storage container 14, the coarse product and the fine pyrolysis residue D have to be sieved again, which increases the number of work steps.
Further, when the coarse material is discharged into the coarse material storage container 14 together with the fine pyrolysis residue D, the coarse material storage container 14 becomes full immediately, and the replacement frequency of the coarse material storage container 14 increases, requiring manual labor. Then there was a problem.
[0013]
The present invention has been made in view of such problems, and the purpose thereof is pyrolysis capable of preventing a fine pyrolysis residue from being mixed in a coarse product sieved by a coarse vibrating screen. It is to provide a residue cooling and conveying facility.
[0014]
[Means for Solving the Problems]
In order to achieve the above object, the invention of claim 1 of the present invention is to convert pyrolysis gas and pyrolysis residue generated in a pyrolysis drum for pyrolyzing waste into pyrolysis gas and pyrolysis residue. A first vibrating feeder, a coarse vibrating screen, a cooling conveyor, a bucket conveyor, and a second vibrating feeder are sequentially arranged in series between the separator to be separated and the sorting apparatus for sorting the separated pyrolysis residue. The material is sealed between the separator and the first vibration feeder and between the second vibration feeder and the sorting device by a pyrolysis residue, and the internal space between the first vibration feeder and the second vibration feeder. Is a pyrolysis residue cooling and transporting facility that maintains a low oxygen atmosphere, wherein the coarse vibrating screen and the bucket conveyor are connected in a continuous manner by a low oxygen gas circulation duct. In both cases, a bag filter and a blower are installed in the low oxygen gas circulation duct, and the low oxygen gas in the bucket conveyor is fed into the coarse vibration screen from the coarse discharge port side of the coarse vibration screen by the low oxygen gas circulation duct and blower. What The low oxygen gas circulation rate is set so that the flow rate of the low oxygen gas in the coarse vibration screen is 0.5 m / sec to 1.0 m / sec, and the low oxygen gas is circulated. The temperature detector detects the temperature on the inlet side of the bag filter in the low oxygen gas circulation duct to prevent the fine pyrolysis residue from being discharged from the coarse material outlet together with the coarse material. The blower was controlled based on the detection signal from the chamber, and the circulation rate of the low oxygen gas was adjusted so that the temperature of the low oxygen gas passing through the bag filter did not exceed the heat resistance temperature of the filter cloth of the bag filter. There is a special feature.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a schematic system diagram of a pyrolysis residue cooling and transporting facility according to an embodiment of the present invention. The pyrolysis residue cooling and transporting facility performs pyrolysis pyrolysis of waste to pyrolysis gas G and pyrolysis residue D. A separator 2 provided on the outlet side of the pyrolysis drum 1 for separating the pyrolysis gas G and the pyrolysis residue D, and a sorting device 3 for sorting the pyrolysis residue D separated by the separator 2 The pyrolysis residue D discharged from the separator 2 is cooled in a low oxygen atmosphere and then conveyed to the sorting device 3.
[0017]
That is, in the pyrolysis residue cooling and conveying equipment, the first vibrating feeder 4, the coarse vibrating screen 5, the cooling conveyor 6, the bucket conveyor 7 and the second vibrating feeder 8 are sequentially arranged in series between the separator 2 and the sorting device 3. The material is sealed between the separator 2 and the first vibration feeder 4 and between the second vibration feeder 8 and the sorting device 3 by the pyrolysis residue D, and the first vibration feeder 4 The internal space between the second vibration feeder 8 is maintained in a low oxygen atmosphere.
In addition, this pyrolysis residue cooling and transporting equipment connects the bulky vibrating screen 5 and the bucket conveyor 7 in communication with each other by a low oxygen gas circulation duct 9, and a bag filter 10 and a fan 11 are connected to the low oxygen gas circulation duct 9. The low oxygen gas in the bucket conveyor 7 is blown into the coarse vibration screen 5.
[0018]
In FIG. 1, 12 is a double damper, 13 is an open / close gate, 14 is a bulk storage container, 15 is an inert gas supply pipe, 16 is a cooling water pipe, 17 is a temperature detector, and 18 is for a blower. A controller, 19 is a pulverizer, 20 is a carbon residue conveyor, 21 is a carbon residue silo, 22 is a carbon residue conduit, and 23 is a carbon residue blower.
[0019]
The first vibrating feeder 4 receives the pyrolysis residue D discharged from the separator 2 and quantitatively discharges it to the subsequent coarse vibrating screen 5 and has a casing formed in an elongated box shape. 24, a plurality of elastic supports 25 that swingably support the casing 24 on the stationary member, and a drive unit 26 such as a vibrator that vibrates the casing 24 with an appropriate vibration force.
The casing 24 has a pyrolysis residue D inlet 24 a connected to the pyrolysis residue outlet 2 a of the separator 2 via a bellows-like flexible hose 27, and a subsequent coarse vibration screen 5 bellows. The outlet 24b of the thermal decomposition residue D connected through the flexible hose 28 is formed.
[0020]
The first vibration feeder 4 is provided with a plurality of level meters 29 (for example, microwave type level sensors) for detecting the amount of stored pyrolysis residue D on the chute portion that forms the inlet 24 a of the casing 24. The drive unit 26 is controlled by a control device (not shown) based on the detection signal, and the storage amount of the pyrolysis residue D is constant by controlling the drive unit 26 and adjusting the vibration force. It can be kept within the range. As a result, the first vibration feeder 4 can quantitatively discharge the pyrolysis residue D to the coarse vibration screen 5, and between the separator 2 and the first vibration feeder 4 by the stored pyrolysis residue D. Can be material sealed.
[0021]
The coarse vibratory screen 5 is used to screen and remove coarse substances (metal wires such as wires and rods and relatively large rubble) contained in the pyrolysis residue D by sieving. The decomposition residue D is discharged to the subsequent cooling conveyor 6, a casing 30 formed in an elongated box shape, a screen 31 (sieving) disposed in the casing 30 to drop and discharge the decomposition residue D, A plurality of elastic supports 32 that swingably support the casing 30 on the fixed side member, and a drive unit 33 such as a vibrator that vibrates the casing 30 with an appropriate vibration force.
The casing 30 has an inlet 30a connected to the outlet 24b of the first vibration feeder 4, and a pyrolysis residue discharge port 30b connected to the subsequent cooling conveyor 6 via a bellows-like flexible hose 34. In addition, a coarse material discharge port 30c connected to the coarse material storage container 14 via a bellows-like flexible hose 35 and a discharge chute 36 is formed.
[0022]
The bulk storage container 14 is detachably connected to the discharge chute 36 so that the bulk storage container 14 can be detached from the bulk vibration screen 5 when the bulk storage container 14 is filled with the bulk. The amount of coarse material stored in the coarse material storage container 14 is measured by a weight meter or level meter (both not shown) provided in the coarse material storage container 14.
In addition, the discharge chute 36 is provided with a slide-type open / close gate 13 that can open and close the coarse discharge port 30 c of the coarse vibration screen 5. This open / close gate 13 is for closing the coarse material discharge port 30c when the coarse material storage container 14 is removed from the coarse material vibration screen 5.
[0023]
The cooling conveyor 6 cools the high-temperature pyrolysis residue D discharged from the coarse vibrating screen 5 to a predetermined temperature (about 80 ° C.) by indirectly cooling with a cooling water W in a low oxygen atmosphere. Then, the cooling conveyor 6 is a water-cooled jacket type vibrating conveyor.
That is, the cooling conveyor 6 includes a casing 37 formed in an elongated box shape, a plurality of elastic supports 38 that swingably support the casing 37 on a fixed member, and vibration that vibrates the casing 37 with an appropriate vibration force. The thermal decomposition residue D is indirectly cooled by flowing the cooling water W from the cooling water pipe 16 into the water cooling jacket 37a provided in the bottom wall portion of the casing 37. Be able to.
Further, the casing 37 is connected to the pyrolysis residue D inlet 37b connected to the pyrolysis residue discharge port 30c of the coarse screen 5 and the subsequent bucket conveyor 7 via the bellows-like flexible hose 40. A pyrolysis residue outlet 37c is formed.
[0024]
The bucket conveyor 7 transports the pyrolysis residue D discharged from the cooling conveyor 6 upward and discharges it to the subsequent second vibratory feeder 8, which is a conventionally known full discharge type bucket conveyor 7. Yes.
That is, the bucket conveyor 7 is formed in a vertically long box shape. The casing 41 has an inlet 41a for the pyrolysis residue D at the lower end and an outlet 41b for the pyrolysis residue D at the upper end. The drive sprocket 42 and the driven sprocket 43 that are rotatably disposed at the upper position and the lower position thereof, the endless chain 44 wound around the sprockets 42 and 43, and the chain 44 are attached at equal intervals. The bucket 45 is composed of a plurality of buckets 45, and receives the pyrolysis residue D when each bucket 45 passes the driven sprocket 43, and also reverses the pyrolysis residue D by reversal when each bucket 45 exceeds the drive sprocket 42. It discharges to the outlet 41b.
[0025]
The second vibratory feeder 8 receives the thermal decomposition residue D discharged from the bucket conveyor 7 and quantitatively discharges it to the subsequent sorting device 3, and includes a casing 46 formed in an elongated box shape, A plurality of elastic supports 47 that swingably support the casing 46 on the fixed side member, and a drive unit 48 such as a vibrator that vibrates the casing 46 with an appropriate vibration force.
Further, the casing 46 has an inlet 46a for the pyrolysis residue D connected to the outlet 41b of the bucket conveyor 7 via a bellows-like flexible hose 49, and a pyrolysis residue D connected to the succeeding sorting device 3. The outlets 46b are respectively formed.
[0026]
The second vibration feeder 8 is provided with a plurality of level meters 50 (for example, microwave level sensors) for detecting the storage amount of the pyrolysis residue D on the chute portion that forms the inlet 46a of the casing 46. The drive unit 48 is controlled by a control device (not shown) based on the detection signal, and the storage amount of the pyrolysis residue D is constant by controlling the drive unit 48 and adjusting the vibration force. It can be kept within the range. As a result, the second vibration feeder 8 can quantitatively discharge the pyrolysis residue D to the sorting device 3, and the material between the second vibration feeder 8 and the sorting device 3 by the stored pyrolysis residue D. Can be sealed.
[0027]
In the pyrolysis residue cooling and conveying equipment, an inert gas G ′ such as nitrogen gas is supplied from the inert gas supply pipe 15 into the casing 37 of the cooling conveyor 6, and the casing 37 of the cooling conveyor 6. The inside is kept in a low oxygen atmosphere. The casing 37 of the cooling conveyor 6 is connected to the casing 30 of the coarse vibration screen 5 and the casing 41 of the bucket conveyor 7 in communication. Therefore, the internal space between the first vibration feeder 4 and the second vibration feeder 8, that is, the coarse vibration screen 5, the cooling conveyor 6, and the bucket conveyor 7 are filled with the inert gas G '. Thus, a low oxygen atmosphere is maintained.
[0028]
Further, in this pyrolysis residue cooling and conveying facility, the coarse object vibrating screen 5 is connected to the coarse substance discharge port 30c side and the upper part of the bucket conveyor 7 in a continuous manner by a low oxygen gas circulation duct 9, and A bag filter 10 and a blower 11 are provided in the oxygen gas circulation duct 9, and the low oxygen gas in the bucket conveyor 7 is passed through the coarse object vibration screen 5 from the coarse substance discharge port 30 c side by the low oxygen gas circulation duct 9. 5 and is blown off to the pyrolysis residue discharge port 30b side to prevent the fine pyrolysis residue D from being discharged together with the coarse material from the coarse material discharge port 30c.
The fine pyrolysis residue (mainly carbon residue D ′) collected by the bag filter 10 is discharged from the bag filter 10 to the carbon residue conveyor 20 through the pyrolysis residue discharge duct 51. .
[0029]
Further, in this pyrolysis residue cooling and conveying equipment, a temperature detector 17 for detecting the temperature on the inlet side of the bag filter 10 is provided in the low oxygen gas circulation duct 9, and based on a detection signal from the temperature detector 17. The blower 11 is controlled, and the circulation amount of the low oxygen gas is adjusted so that the temperature of the low oxygen gas passing through the bag filter 10 does not exceed the set temperature.
In other words, the temperature detector 17 detects the temperature on the inlet side of the bag filter 10, and when this temperature exceeds the set temperature (heat resistance temperature of the filter cloth of the bag filter 10), an alarm is issued and the detection from the temperature detector 17 is performed. A signal is input to the blower controller 18, and the blower 11 is controlled by the control signal from the blower controller 18 so that the circulation amount of the low oxygen gas is reduced.
[0030]
The circulation amount of the low oxygen gas is set so that the flow rate of the low oxygen gas in the coarse vibration screen 5 is 0.5 m / sec to 1.0 m / sec. This is because if the flow rate of the low oxygen gas is less than 0.5 m / sec, the fine pyrolysis residue D cannot be prevented from entering the coarse substance storage container 14, and the flow rate of the low oxygen gas is 1. This is because when the temperature exceeds 0 m / sec, the temperature of the circulating low oxygen gas increases and the filter cloth of the bag filter 10 may be burned out (the heat resistance temperature of the current filter cloth is about 80 ° C.). .
Further, excess low oxygen gas is discharged to the outside from a branch pipe connected to the low oxygen gas circulation duct 9 in a branched manner.
[0031]
Next, the case where the thermal decomposition residue D discharged | emitted from the separator 2 is conveyed to the sorting apparatus 3 using the thermal decomposition residue cooling conveyance equipment comprised as mentioned above is demonstrated.
[0032]
The pyrolysis gas G and pyrolysis residue D obtained by pyrolysis of waste in the pyrolysis drum 1 are introduced into a separator 2 adjacent to the pyrolysis drum 1, where pyrolysis is performed by gravity. The gas G and the thermal decomposition residue D are separated.
The pyrolysis gas G is directly introduced into a combustion melting apparatus (not shown) via a pyrolysis gas conduit (not shown) and burned at a high temperature, and the pyrolysis residue D is pyrolyzed by the separator 2. It is dropped and discharged from the residue outlet 2a into the casing 24 of the first vibration feeder 4.
[0033]
The pyrolysis residue D discharged to the inlet 24a (in the chute) of the first vibration feeder 4 is stored in a certain amount in the inlet 24a and seals between the separator 2 and the coarse vibration screen 5, while the casing 24 The inside of the casing 24 is moved from the inlet 24a side to the outlet 24b side by the vibration action, and is dropped and discharged from the outlet 24b into the casing 24 of the coarse vibration screen 5.
[0034]
At this time, in the first vibration feeder 4, the storage amount of the pyrolysis residue D stored in the inlet 24 a is detected by the level meter 29 disposed in the inlet 24 a, and based on the detection signal from the level meter 29. The vibration force of the first vibration feeder 4 is adjusted so that the storage amount of the pyrolysis residue D stored in the inlet 24a becomes a constant amount. Accordingly, the pyrolysis residue D is quantitatively discharged from the first vibration feeder 4 to the coarse vibration screen 5.
[0035]
The pyrolysis residue D discharged into the bulky vibrating screen 5 is subjected to a vibrating action on the screen 31, and the bulky materials (metal wires and relatively large debris) contained in the pyrolysis residue D are selected. Removed. That is, the fine pyrolysis residue D on the screen passes through the eyes of the screen 31 by the vibration action of the screen 31 and is dropped and discharged from the pyrolysis residue discharge port 30 b into the casing 37 of the cooling conveyor 6. The coarse material remaining on the screen 31 is moved from the inlet 30a side to the coarse material discharge port 30c side by the vibration action of the screen 31, and is dropped and discharged from the coarse material discharge port 30c into the coarse material storage container 14. .
[0036]
At this time, in the coarse vibration screen 5, the low oxygen gas (mainly inert gas G ′) in the bucket conveyor 7 is discharged from the coarse vibration screen 5 by the low oxygen gas circulation duct 9 and the blower 11. Since the air is blown into the coarse vibration screen 5 from the outlet 30c side, the fine pyrolysis residue D transferred to the coarse discharge port 30c side in the casing 30 and the fine pyrolysis residue D adhering to the coarse material In addition, the fine pyrolysis residue D floating in the atmospheric gas is blown off to the pyrolysis residue discharge port 30b side. As a result, the fine pyrolysis residue D in the casing 30 and the fine pyrolysis residue D adhering to the coarse material are prevented from being discharged together with the coarse material into the coarse material storage container 14 from the coarse material discharge port 30c. Can do.
Further, in the coarse vibration screen 5, since the thermal decomposition residue D is quantitatively discharged from the first vibration feeder 4, the sieving by the coarse vibration screen 5 can be performed well and reliably. .
[0037]
The low oxygen gas blown into the coarse vibration screen 5 has a fine pyrolysis residue (mainly carbon residue D ′) removed by the bag filter 10, so that the blower 11 may be broken due to the pyrolysis residue D. None. The carbon residue D ′ removed by the bag filter 10 is discharged to the carbon residue conveyor 20 through the pyrolysis residue discharge duct 51.
The circulation amount of the low oxygen gas is such that the temperature of the low oxygen gas passing through the bag filter 10 does not exceed the heat resistance temperature of the filter cloth in the bag filter 10, the temperature detector 17 and the controller for the air blower. Therefore, the filter cloth is prevented from being burned out by the low oxygen gas.
[0038]
The relatively fine pyrolysis residue D discharged to the cooling conveyor 6 moves in the casing 37 from the inlet 37b side to the outlet 37c side by the vibration action of the casing 37, and the cooling water W in the low oxygen atmosphere. Is indirectly cooled, and is dropped and discharged from the outlet 37 c into the casing 41 of the bucket conveyor 7.
[0039]
At this time, since the pyrolysis residue D is cooled in a low oxygen atmosphere, combustion, explosion, and the like of the pyrolysis residue D are prevented.
In the cooling conveyor 6, since the pyrolysis residue D is quantitatively discharged from the first vibration feeder 4, the flow of the pyrolysis residue D on the cooling conveyor 6 is substantially uniform or has a constant thickness. become. As a result, the cooling effect of the cooling conveyor 6 is improved.
[0040]
The cooled pyrolysis residue D discharged into the bucket conveyor 7 is put into the bucket 45 and conveyed upward, and then discharged from the bucket 45 to the outlet 41b side into the casing 46 of the second vibration feeder 8. Discharged.
In addition, since the bucket conveyor 7 conveys the thermal decomposition residue D after a coarse thing is removed, the apparatus itself can be reduced in size.
[0041]
The pyrolysis residue D discharged to the inlet 46a (in the chute) of the second vibration feeder 8 is stored in a certain amount in the inlet 46a and seals between the bucket conveyor 7 and the sorting device 3 while vibrating the casing 46. Thus, the casing 46 moves from the inlet 46a side to the outlet 46b side, and is discharged from the outlet 46b into the sorting device 3.
[0042]
At this time, in the second vibration feeder 8, the storage amount of the pyrolysis residue D stored in the inlet 46 a is detected by the level meter 50 disposed in the inlet 46 a, and based on the detection signal from the level meter 50. The vibration force of the second vibration feeder 8 is adjusted so that the storage amount of the pyrolysis residue D stored in the inlet 46a becomes a constant amount. Accordingly, the pyrolysis residue D is quantitatively discharged from the second vibration feeder 8 to the sorting device 3.
[0043]
The pyrolysis residue D discharged into the sorting device 3 is made of iron, aluminum, rubble (stones, concrete pieces, glass pieces, etc.), carbon by a magnetic separator, a vibrating screen and an aluminum sorter (all not shown). Each residue D ′ is subjected to a sorting process.
In the sorting device 3, since the pyrolysis residue D is quantitatively discharged from the second vibration feeder 8, the sorting device 3 needs to be designed based on the maximum discharge amount of the pyrolysis residue D. Therefore, the device itself can be reduced in size.
[0044]
Iron, aluminum and rubble sorted by the sorting device 3 are respectively stored in a bunker (not shown), and a relatively large carbon residue D ′ is pulverized to about 1 mm or less by a pulverizer 19 to be a carbon residue conveyor. 20 is transported to a carbon residue silo 21 and temporarily stored therein, and is then pneumatically transported by a carbon residue blower 23 and a carbon residue conduit 22 to be sent to a melting combustion apparatus (not shown). In this case, it is melted and burned together with the pyrolysis gas G to form molten slag.
[0045]
When the pyrolysis residue cooling and transporting facility is operated for a long time, the coarse material is accumulated in the coarse material storage container 14, and the coarse material storage container 14 is filled. Then, the open / close gate 13 is closed to close the coarse discharge port 30c of the coarse vibration screen 5, and the worker manually replaces the coarse storage container 14 with a new one.
[0046]
At this time, since only the coarse material is stored in the coarse material storage container 14, it is not necessary to newly screen the coarse material taken out from the coarse material storage container 14, and the work process can be reduced.
In addition, since only the coarse material is discharged to the coarse material storage container 14, the coarse material storage container 14 does not immediately fill up, and the replacement frequency of the coarse material storage container 14 can be reduced. Less is enough.
When the pyrolysis residue cooling and transporting facility of the present invention was used, the replacement frequency of the bulk storage container 14 was greatly reduced compared to the conventional pyrolysis residue cooling and transporting facility. That is, when the pyrolysis residue cooling and transporting facility of the present invention was used, the replacement frequency of the bulk storage container 14 decreased from twice a day to once every two days.
[0047]
【The invention's effect】
As is apparent from the above description, the pyrolysis residue cooling and transporting facility according to claim 1 of the present invention connects the coarse vibrating screen and the bucket conveyor in a continuous manner by the low oxygen gas circulation duct, and this low oxygen A bag filter and a blower are installed in the gas circulation duct, and low oxygen gas in the bucket conveyor is blown into the coarse vibration screen from the coarse discharge port of the coarse vibration screen by the low oxygen gas circulation duct and blower. Therefore, the fine pyrolysis residue in the coarse screen, the fine pyrolysis residue adhering to the coarse material, and the fine pyrolysis residue floating in the atmospheric gas will be blown away, and the fine pyrolysis residue will be blown away. It is possible to prevent discharge from the coarse material discharge port together with the coarse material.
As a result, it is not necessary to screen the coarse material taken out from the coarse material storage container, and the work process can be reduced. However, the bulk storage container does not become full immediately, and the replacement frequency and labor of the bulk storage container can be reduced.
In the pyrolysis residue cooling and transporting facility of the present invention, the first vibrating feeder, the coarse vibrating screen, the cooling conveyor, the bucket conveyor and the second vibrating feeder are sequentially arranged in series between the separator and the sorting device. Since the material is sealed between the separator and the first vibration feeder and between the second vibration feeder and the sorting device by the pyrolysis residue, the interior between the first vibration feeder and the second vibration feeder. The space can be maintained in a low oxygen atmosphere in a good and reliable manner.
[0048]
Furthermore, the pyrolysis residue cooling and conveying equipment of the present invention is A temperature detector that detects the temperature on the bag filter inlet side is installed in the low oxygen gas circulation duct, the blower is controlled based on the detection signal from the temperature detector, and the temperature of the low oxygen gas passing through the bag filter is set Since the circulation amount of the low oxygen gas is adjusted so as not to exceed the temperature, it is possible to prevent the filter cloth of the bag filter from being burned out by the low oxygen gas.
[Brief description of the drawings]
FIG. 1 is a schematic system diagram of a pyrolysis residue cooling transfer facility according to an embodiment of the present invention.
FIG. 2 is a schematic system diagram of a conventional pyrolysis residue cooling transfer facility.
[Explanation of symbols]
1 is a pyrolysis drum, 2 is a separator, 3 is a sorting device, 4 is a first vibrating feeder, 5 is a coarse vibrating screen, 6 is a cooling conveyor, 7 is a bucket conveyor, 8 is a second vibrating feeder, and 9 is low. Oxygen gas circulation duct, 10 is a bag filter, 11 is a blower, 17 is a temperature detector, D is a pyrolysis residue, and G is a pyrolysis gas.

Claims (1)

Separator for separating pyrolysis gas and pyrolysis residue generated in pyrolysis drum for pyrolyzing wastes into pyrolysis gas and pyrolysis residue, and sorting device for sorting the separated pyrolysis residue The first vibration feeder, the coarse vibration screen, the cooling conveyor, the bucket conveyor, and the second vibration feeder are arranged in series between the separator and the first vibration feeder and the second vibration. It is a pyrolysis residue cooling and conveying facility that seals the material between the feeder and the sorting device with pyrolysis residue and keeps the internal space between the first vibration feeder and the second vibration feeder in a low oxygen atmosphere. The coarse vibration screen and the bucket conveyor are connected in a continuous manner by a low oxygen gas circulation duct, and a bag filter and a low oxygen gas circulation duct are connected to the low oxygen gas circulation duct. Interposed wind machine, with blowing low oxygen gas in the bucket conveyor to hypoxia gas circulation duct and the blower by coarse material vibrating screen of coarse material discharge port side from the coarse material vibrating screen within a circulation amount of the hypoxic gas The flow rate of the low oxygen gas in the coarse screen is set to 0.5m / sec to 1.0m / sec. By circulating the low oxygen gas, fine pyrolysis residue is mixed with the coarse product. A temperature detector that detects the temperature on the inlet side of the bag filter is installed in the low-oxygen gas circulation duct to prevent exhaust from the coarse material outlet, and the blower is controlled based on the detection signal from the temperature detector. and, characterized in that the temperature of the low oxygen gas passing through the bag filter is to adjust the circulation amount of the low-oxygen gas so as not to exceed the heat resistance temperature of the filter cloth bag filter Pyrolysis residue cooled transport facility to.

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