HIGH TEMPERATURE GAS REFORMING CYCLO-INCπ ERATOR
Technical Field
The present invention relates, in general, to high temperature gas reforming incinerators and, more particularly, to a high temperature gas reforming cyclo-incinerator, which has an air cooling structure designed to strongly swirl inlet air in the incinerator prior to discharging the air from the incinerator, thus increasing circulation time of the inlet air in the incinerator, and a heat shielding structure using a heat shielding plate designed to prevent heat dissipation from the external surface of the incinerator and protect a user from being burned by dissipated heat, and which also keeps a fire alive until wastes in the incinerator are completely burned up, feeds fuel to completely incinerate incompletely burned wastes, and collects and temporarily stores dust-laden air generated from the combustion of the wastes prior to filtering the air to remove dust from the air and discharging clean air to the atmosphere.
Background Art
Present-day cities generate a great quantity of wastes, such as domestic refuse, garbage and industrial wastes, which are not recyclable and are prohibited from being buried, but are combustible. The disposal of such wastes has been typically accomplished by incineration of them. In order to incinerate such wastes, large-scaled incineration equipments are installed at neighborhood areas of the cities.
However, the conventional large-scaled incineration equipments are problematic in that they are accompanied by excessive costs for installation and operation of them, and generate exhaust gas laden with harmful substances, such as nitrogen oxides and dioxin, the contents of which exceed allowable levels to
severely contaminate atmospheric air.
In an effort to overcome the problems experienced in such conventional large-scaled incineration equipments, the inventor of this invention proposed "a gas reforming incinerator" as disclosed in Korean Patent Laid-open Publication No. 99-78939. This gas reforming incinerator comprises a lower external tub, which consists of a cylindrical body, with a flange provided at each end of the body. First and second combustion chambers are provided in the lower external tub. The first combustion chamber has a combustion tub, which is provided with a flange at its lower end and an annular-shaped control water supply pipe at its upper end. The second combustion chamber has an air feed tub, which is provided with a flange at each end thereof and an air inlet hole at the sidewall thereof. A sub-combustion tub is received in the air feed tub. This incinerator also has an upper external tub, which has a flange at each end thereof and receives therein a dust collecting tub with a dust collecting means. The above gas reforming incinerator is a new type of incinerator, which is preferably used for burning up a variety of combustible wastes, such as domestic refuses, waste plastics, waste rubber, waste food, waste tires, medical refuses, waste oil, and livestock wastes, which are not recyclable. This gas reforming incinerator almost completely burns up the wastes through pyrolysis using very high temperature heat of about 1800 °C, thus accomplishing complete combustion of the wastes without generating smoke or odor and thereby almost completely removing harmful gases, such as carbon monoxides, nitrogen oxides, or sooty smoke, from its exhaust gas.
However, the conventional gas reforming incinerator is problematic in that it only allows inlet air to circulate in its interior for a short period of time even though it has a complex structure for creating the inlet air circulation. In addition, this gas reforming incinerator is inferior in its heat shielding function, thus sometimes causing a user to unexpectedly be burned by heat dissipated from its external surface. Another problem of the conventional gas reforming incinerator
resides in that it is necessary to carry out complex processes to completely burn up incompletely burned wastes. Furthermore, the above incinerator undesirably discharges harmful dust along with exhaust gas to the atmosphere.
Disclosure of the Invention
Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a high temperature gas reforming cyclo-incinerator, which has an air cooling structure designed to strongly swirl inlet air in the incinerator prior to discharging the air from the incinerator, thus lengthening circulation time of the inlet air in the incinerator, and a heat shielding structure using a heat shielding plate designed to prevent heat dissipation from the external surface of the incinerator and protect a user from being burned by dissipated heat, and which also keeps a fire alive until wastes in the incinerator are completely burned up, feeds fuel to completely burn up incompletely burned wastes, and collects and temporarily stores dust-laden air generated from the combustion of the wastes prior to filtering the air to remove dust from the air and discharging clean air to the atmosphere.
Brief Description of the Drawings
The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:
Fig. 1 is an exploded perspective view of an incinerator in accordance with the preferred embodiment of the present invention;
Fig. 2 is an exploded side sectional view of the incinerator according to this invention;
Fig. 3 is a side sectional view showing an operation of the incinerator according to this invention;
Fig. 4 is a plan sectional view showing an arrangement of tubs in the incinerator according to this invention; and Fig. 5 is an enlarged side sectional view showing an operation of a dust collecting tub included in the incinerator according to this invention.
Best Mode for Carrying Out the Invention
Reference now should be made to the drawings, in which the same reference numerals are used throughout the different drawings to designate the same or similar components.
Fig. 1 is an exploded perspective view of a high temperature gas reforming cyclo-incinerator in accordance with the preferred embodiment of the present invention. Fig. 2 is an exploded side sectional view of the above incinerator. Fig. 3 is a side sectional view showing an operation of the above incinerator. As shown in the drawings, the high temperature gas reforming cyclo- incinerator "A" comprises an internal exhaust tub 90 and an external exhaust tub 80, which are used for exhausting combustion gases from the incinerator to the atmosphere. The incinerator also has an internal upper tub 60 and an external upper tub 50, which rapidly swirls heat and gas therein and guides them to the internal exhaust tub 90 and the external exhaust tub 80. The incinerator further includes an internal lower tub 10 and an external lower tub 30, which form a passage for putting wastes into the incinerator, define a combustion chamber for completely burning up the wastes using appropriately controlled fuel and reformed water while creating rapid swirling flow of air therein, and from which ashes are discharged to the outside of the incinerator.
The external exhaust tub 80 comprises a cylindrical body, which has a skirt 82 at its lower end with a lower flange 84 formed along the outside edge of
the skirt 82. A first sensor fitting hole 88 is formed at the central portion of the cylindrical sidewall of the external exhaust tub 80, and receives an exhaust gas sensor holder 89 therein. The external exhaust tub 80 also has a second sensor fitting hole 86 at a predetermined position on the junction of the cylindrical body and the skirt 82, and receives a temperature sensor 67a therein.
The internal exhaust tub 90 comprises a cylindrical body, which is provided with a top flange 94 along its upper end. This internal exhaust tub 90 is axially received into the external exhaust tub 80 until the top flange 94 is seated on the upper end of the external exhaust tub 80. A plurality of exhaust ports 92 are formed around the circumferential surface of the upper end of the internal exhaust tub 90. A third sensor fitting hole 96 is formed at the central portion of the cylindrical sidewall of the internal exhaust tub 90, and receives the tip of the exhaust gas sensor holder 89.
The internal upper tub 60 has a cylindrical tub body 61, with an exhaust pipe 66 axially extending from the upper end of the body 61. The exhaust pipe
66 of the internal upper tub 60 is inserted into the lower end of the internal exhaust tub 90 while forming a gap between the external surface of the exhaust pipe 66 and the internal surface of the internal exhaust tub 90. Due to the gap formed between the external surface of the exhaust pipe 66 and the internal surface of the internal exhaust tub 90, the exhaust pipe 66 is thermally expanded or contracted during an operation of the incinerator "A". A shoulder 64 is formed at the lower end of the exhaust pipe 66, and is integrated with the upper end of the cylindrical tub body 61 into a single structure. A fourth sensor fitting hole 67 is formed at the central portion of the cylindrical sidewall of the exhaust pipe 66, and receives the tip of the temperature sensor 76a.
A stop rim 65 is formed around the upper end of the tub body 61, while a plurality of exhaust ports 63 are formed around the upper end of the sidewall of the tub body 61 at a position under the stop rim 65. A heat shielding plate 68 surrounds the upper portion of the tub body 61 at a position under the stop rim 65.
A dust collector 62 is installed within the lower portion of the tub body 61, while an internal intake opening 69 is formed at the lower portion of the tub body 61. An internal intake door 70 having a transparent window 72 is rotatably mounted to the edge of the intake opening 69 using hinges 74, and is openably locked to the tub body 61 using a locking member 76.
The external upper tub 50 comprises a cylindrical body, with an upper flange 54 formed at the upper end of the external upper tub 50. The external upper tub 50 also has an internal support rim 52 for seating the stop rim 65 of the internal upper tub 60 thereon. The internal lower tub 10 comprises a cylindrical body, with a plurality of inlet ports 11a, l ib and lie formed at the upper and lower portions of the cylindrical sidewall of the internal lower tub 10. An internal ash outlet opening 15 is formed at the lower portion of the internal lower tub 10, and is covered with a window 15 a. A bottom plate 16 is mounted to the lower end of the internal lower tub 10. The bottom plate 16 is fixed to the top surface of a base plate 180.
A water collector 14 is connected to the central portion of the bottom plate 16. A plurality of water outlet ports l id are formed around the cylindrical sidewall of the internal lower tub 10 at a position above the lower end of the water collector 14. A plurality of water inlet ports l ie are formed around the lower portion of the cylindrical sidewall of the internal lower tub 10.
The outlet ports lid and the inlet ports lie, formed on the sidewall of internal lower tub 10, are externally covered with a water-collecting tub 12 such that the water-collecting tub 12 collects reformed water flowing from the outlet ports l id. The reformed water is, thereafter, introduced into the internal lower tub 10 through the inlet ports lie.
A perforated plate 18, having a plurality of through holes 18a, is fixedly mounted in the internal lower tub 10 at a position under the inlet ports l ie, while a firebrick stack 19 is formed at the lower portion inside the internal lower tub 10 at a position between the inlet ports l ie and the perforated plate 18. The bottom
plate 16, mounted to the lower end of the internal lower tub 10, has a drain spout 17 at the center thereof.
During an operation of the incinerator, reformed water flows down along the internal surface of the internal lower tub 10, and passes through the water- collecting tub 12 by way of the water collector 14, and is collected on the bottom plate 16. When the reformed water is collected on the bottom plate 16 as described above, the drain spout 17 discharges the reformed water from the incinerator to the outside. A drain tub 20 having a drain port 22 is connected to the lower end of the drain spout 17 using a drain tub fixing plate 24. The external lower tub 30 is fitted over the internal lower tub 10, and comprises an upper cylindrical body 36 and a lower cylindrical body 31. The upper body 36 of the external lower tub 30 has an air inlet port 37 at the central portion of its cylindrical sidewall, with an external intake opening 39 formed on the sidewall of the upper body 36 at a position diametrically opposite to the air inlet port 37. An external intake door 39a having a transparent window 39b is rotatably mounted to the edge of the external intake opening 39 using hinges 39c, and is openably locked to the upper body 36 using a locking member 39d.
The upper end of the lower body 31 of the external lower tub 30 is connected to the lower end of the upper body 36, with the heat shielding plate 35 covering a part of the upper portion of the lower body 31 and an external ash outlet opening 33 formed at the lower portion of the lower body 31. A slidable ash outlet door 34 having a window 34a covers the ash outlet opening 33, while a dust collecting port 32 is formed on the lower portion of the lower body 31 at a position diametrically opposite to the ash outlet opening 33. A plurality of inlet ports 31a, 31b and 31c are formed at the upper and lower portions of the cylindrical sidewall of the lower body 31.
Two annular-shaped fuel inlet pipes 110 and 120 receive fuel from an external fuel tank (not shown), and spray the fuel through their nozzles 112 and 122 at the upper and lower portions of the interior of the internal lower tub 10 so as
to accomplish complete combustion of wastes. The two fuel inlet pipes 110 and 120 are fixedly set in the upper and lower portions inside the internal lower tub 10, respectively, and are commonly connected to the external fuel tank (not shown) through the inlet ports l ib and l ie of the internal lower tub 10 and the inlet ports 3 lb and 31c of the external lower tub 30.
An annular-shaped reformed water inlet pipe 100 receives reformed water from an external reformed water tank (not shown), and sprays the reformed water through its nozzles 102 at the upper portion of the interior of the internal lower tub 10, thus accomplishing complete combustion of the wastes. The reformed water inlet pipe 100 is fixedly set in the upper portion inside the internal lower tub 10, and is connected to the external reformed water tank (not shown) through the inlet port 11a of the internal lower tub 10 and the inlet port 31a of the external lower tub 30.
A disc-shaped positioning plate 150, having a seating opening 152 at its central portion, is mounted to the lower end of the internal lower tub 10. This positioning plate 150 also has a plurality of locking pieces 154, which are formed on the lower surface of the plate 150 and partially project into the opening 152.
A fire grate 140 is seated on the seating opening 152 of the positioning plate 150. This fire grate 140 consists of a disc-shaped body provided with a plurality of through holes 142. A guide ring 146 is concentrically mounted to the upper surface of the fire grate 140, while a positioning pipe 144 is mounted to the center of the fire grate 140.
A flame stabilizer 130 is mounted to the upper surface of the fire grate 140, and is used for maintaining the flame of the fire grate 140 for a desired lengthy period of time. This flame stabilizer 130 consists of an annular upper plate 138, with a plurality of support pipes 136 vertically mounted along the edge of the lower surface of the upper plate 138. In the cylindrical space defined by the support pipes 136, a disc-shaped lower plate 134 is mounted to the middle portions of the support pipes 136 at its outside edge. A positioning piece 132 is
mounted to the center of the lower surface of the lower plate 134. The positioning piece 132 is fitted into the positioning pipe 144 of the fire grate 140.
Fig. 4 is a plan sectional view showing the arrangement of the tubs in the incinerator of this invention. As shown in the drawing, an air guide pipe 37b extending from a fan unit 37a is tangentially connected to the air inlet port 37 formed at the cylindrical sidewall of the upper body 36 of the external lower tub 30, and so external air fed from the fan unit 37a into the incinerator "A" rapidly swirls in the incinerator.
In the incinerator of this invention, the internal intake door 70 and the external intake door 39a are respectively hinged to the edges of the intake openings
69 and 39 of the internal upper tub 60 and the external lower tub 30 using the hinges 74 and 39a, and are openably locked to the tubs 60 and 30 using the locking members 76 and 39d. Of course, the two intake openings 69 and 39 are aligned with each other. A support plate 36a closes the lower end of the annular gap defined between the internal intake door 70 of the internal upper tub 60 and the external intake door 39d of the external lower tub 30, and so input wastes are not dropped to the lower portion outside the cylindrical tub body 61 of the internal upper tub 60, but desirably slide into the interior of the tub body 61.
A heat shielding plate 38 is set within the external lower tub 30 at a position covering the junction of the upper and lower cylindrical bodies 36 and 31 of the external lower tub 30. This heat shielding plate 38 intercepts combustion heat generated from the interior of the tub body 61 during the waste combustion process, thus preventing the heat from being transferred to the lower portion of the upper body 36 or the upper portion of the lower body 31 of the external lower tub 30. The combustion heat, intercepted by the heat shielding plate 38, is transmitted into the external lower tub 30 through the air inlet port 37 by the blowing force of the fan unit 37a, thus being effectively dissipated by the swirling air currents.
The disc-shaped positioning plate 150 is mounted to the lower end of the
incinerator so as to support the fire grate 140 assembled with the flame stabilizer 130. The fire grate 140 has the through holes 142 on its body, with the guide ring 146 concentrically mounted to the upper surface of the fire grate 140.
Fig. 5 is an enlarged side sectional view showing an operation of the dust collecting tub included in the incinerator of this invention. As shown in the drawing, a dust guide pipe 43 is connected at a first end thereof to the dust collecting port 32 of the external lower tub 30, and is connected at its second end to a dust collecting tub support member 41. The lower end of a dust collecting tub 40 is vertically fitted into the upper end of the support member 41, such that the second end of the dust collecting tube 44 is inserted into the lower end of the dust collecting tub 40. Therefore, dust-laden air generated in the incinerator "A" is guided into the dust collecting tub 40 through the dust guide pipe 43, and so dust is removed from the air before the air is discharged from the incinerator.
The dust collecting tub support member 41 is a tubular member, which is mounted to the base plate 180 and receives the second end of the dust guide pipe
43, with the dust collecting tub 40 vertically fitted into the upper end of the support member 41.
A dust guide tube 44 axially and concentrically extends upward from the bottom in the dust collecting tub 40 to a height, with an air filter 46 set in the upper portion of the dust collecting tub 40 at a position above the dust guide tube 44. A plurality of dust outlet ports 42 are formed at the upper portion of the dust collecting tub 40, while a top lid 48 openably covers the upper end of the dust collecting tub 40.
The top lid 48 of the dust collecting tub 40 has a pump "P", thus forcibly expelling filtered air from the tub 40. The top lid 48 of the dust collecting tub 40 may be connected to the incinerator "A" through a pipe such that filtered air is fed from the top lid 48 into the incinerator "A" by a pumping action of the pump "P".
The above gas reforming cyclo-incinerator "A" of this invention is operated as follows.
When it is desired to burn up, using the incinerator of this invention, a variety of combustible wastes, such as domestic refuses, waste plastics, waste rubber, waste food, waste tires, medical refuses, waste oil, and livestock wastes, which are not recyclable, a user opens the external intake door 39a of the external lower tub 30 of the incinerator "A" installed on the base plate 180, thus opening the external intake opening 39. Thereafter, the user opens the internal intake door 70 of the tub body 61 of the internal upper tub 60, thus opening the internal intake opening 69.
In order to open the two doors 39 and 69, the user releases the locking members 39d and 76 and rotates the doors 39 and 69 around the hinges 39c and 74.
After opening the two intake openings 39 and 69, the user inputs a desired quantity of wastes into the incinerator "A" through the two intake opening 39 and 69 such that the input wastes are stacked at a position above the positioning plate 150, the fire grate 140 and the flame stabilizer 130 in the internal lower tub 10. Thereafter, the input wastes are ignited using a manual igniter or an automatic igniter (not shown). After the ignition of the wastes, the two intake doors 70 and 39a are sequentially closed prior to locking the doors 70 and 39a using the locking members 76 and 39d, thus completely closing the two intake openings 69 and 39.
Thereafter, the user controls a control panel 160 of the incinerator "A" to turn on the fan unit 37a, thus forcibly feeding external air into the incinerator "A" through the air inlet port 37. At the same time, a predetermined quantity of reformed water is fed from the external reformed water tank (not shown) into the internal lower tub 10 through the nozzles 102 of the reformed water inlet pipe 100.
The reformed water, sprayed into the internal lower tub 10 from the nozzles 102 of the reformed water inlet pipe 100 set in the upper portion of the internal lower tub 10, greatly increases humidity inside the incinerator "A". In such a case, the external air having a relatively lower temperature than that of the reformed water rapidly swirls around the external surface of the sidewall of the internal lower tub 10, and so reformed water drops are formed on the internal
surface of the sidewall of the internal lower tub 10 and flow down said internal surface.
The reformed water drops, flowing down the internal surface of the sidewall of the internal lower tub 10, are collected by the water collector 14 installed inside the internal lower tub 10. The reformed water collected by the water collector 14 flow through the water outlet ports lid so as to be fed into the water-collecting tub 12 installed outside the internal lower tub 10. The reformed water collected in the water-collecting tub 12 flows into the internal lower tub 10 through the water inlet ports l ie, which are formed around the lower portion of the cylindrical sidewall of the internal lower tub 10.
When the reformed water flows into the internal lower tub 10 through the water inlet ports lie, the reformed water is dropped onto the firebrick stack 19 formed at the lower portion inside the internal lower tub 10. In such a case, the firebrick stack 19 is heated by radiant heat, and so a part of the reformed water is vaporized to generate steam and the steam flows upward through the through holes
142 of the fire grate 140.
The remaining part of the reformed water dropped onto the firebrick stack 19 passes through the gaps between the firebricks of the stack 19, and is dropped onto the bottom plate 16 through the through holes 18a of the perforated plate 18. The reformed water dropped onto the bottom plate 16 is, thereafter, discharged into the drain tub 20 while sequentially passing through the drain spout 17 of the bottom plate 16, and the drain port 22 of the drain tub 20 connected to the lower end of the drain spout 17. In such a case, the drain port 22 is supported by the drain tub fixing plate 24 provided inside the drain tub 20. In the operation of the incinerator, external air is forcibly fed from the fan unit 37a into the internal lower tub 10 through the air inlet port 37 of the external lower tub 30. The external air strongly swirls in the external lower tub 30 in a counterclockwise direction to form strong vortex flow since the air tangentially flows into the tub 30. In such a case, a part of the inlet air swirls upward to the
external upper tub 50. The remaining part of the inlet air swirls downward to the lower portion of the external lower tub 30, and is heated by high temperature heat, thus swirling upward to be introduced into the internal upper tub 60 and the internal lower tub 10. The inlet air, rapidly and continuously flowing into both the internal upper tub 60 and the internal lower tub 10 and counterclockwise swirling in said tubs 60 and 10, is mixed with the atomized reformed water sprayed from the nozzles 102 of the water inlet pipe 100, and rapidly swirls counterclockwise in the gap between the external lower tub 30 and the internal upper tub 60 and in the spaces inside the internal upper tub 60 and the internal lower tub 10.
The rapidly swirling inlet air, having a low temperature, is introduced into the upper body 36 of the external lower tub 30, and rapidly swirls in the gap between the external upper tub 50 and the internal upper tub 60 and in the gap between the external lower tub 30 and the internal lower tub 10 while being heated to a high temperature.
The hot air rapidly swirls upward to the external upper tub 50, and is introduced into the spaces inside the internal upper tub 60 and the internal lower tub 10 so as to rapidly swirl upward in said spaces. In such a case, the hot air swirling upward in the internal upper tub 60 comes into contact with the sidewall of said tub 60. The sidewall of the internal upper tub 60 is cooled by the inlet air newly fed from the fan unit 37a to the external surface of said sidewall, and so the hot air inside the internal upper tub 60 is cooled by the sidewall of the tub 60 and becomes cool air and flowing downward in the tub 60.
The cool air flowing downward in the tub 60 is introduced into the internal lower tub 10, and is heated in said tub 10 to become hot air. This hot air rapidly swirls upward in the internal lower tub 10. The inlet air, introduced into the incinerator "A", thus repeatedly circulate in said incinerator "A".
Therefore, combustion gas generated from the combustion of wastes in the incinerator "A" repeatedly circulates in the incinerator for a lengthy period of
time while being mixed with inlet air, and so the combustion gases repeatedly come into contact with hot air of about 1,800 °C in the incinerator to be almost completely decomposed through pyro lysis. That is, the combustion gases are completely burned up, and exhaust gas from the incinerator is not likely to include harmful gases.
In addition, inlet air rapidly swirls in the gap between the external upper tub 50 and the internal upper tub 60 and in the gap between the internal lower tub 10 and the external lower tub 30. Therefore, the external surfaces of the sidewalls of both the external upper tub 50 and the external lower tub 30 are not excessively heated, and so a user can be prevented from being burned even though he touches the external surfaces of the tubs 30 and 50.
A part of inlet air rapidly swirling in the gap between the external upper tub 50 and the internal upper tub 60 is exhausted from the incinerator to the atmosphere as exhaust gas. hi such a case, a part of the exhaust gas sequentially passes through the gap between the heat shielding plate 68 of the internal upper tub
60 and the upper portion of the tub body 61, the exhaust ports 63 formed at the upper end of the tub body 61, and the gap between the external surface of the exhaust pipe 66 and the internal surface of the internal exhaust tub 90 prior to being discharged to the atmosphere. The remaining part of the exhaust gas sequentially passes through the gap between the external exhaust tub 80 and the internal exhaust tub 90 and the exhaust ports 92 formed at the upper end of the internal exhaust tub 90 prior to being discharged to the atmosphere.
When burning up the wastes in the incinerator of this invention, inlet air mixed with reformed water is fed into the internal lower tub 10, and undergoes chemical reactions, that is, a pyrolytic reaction (reforming reaction) expressed by the reaction formula {C, H + H2 -» CO + H2}, and a combustion reaction expressed by the reaction formula {(CO + H2) + O2 -» CO2 + H2O}, in the incinerator, thus supplying plentiful oxygen (O2) to the flame in the tub 10. The temperature of the flame of the wastes is thus increased to a very high point of
about 1,800 °C at its center, thus accomplishing complete combustion of the wastes through pyrolysis.
Due to the pyrolysis, exhaust gas discharged from the incinerator of this invention is not likely to include smoke, dust, and harmful substances, such as CO, NOx, SOx and dioxin.
That is, during an incineration of wastes in the incinerator "A" of this invention, thermal energy generated from the incineration vaporizes water and performs destructive distillation in which solid organic materials are subjected to pyrolysis to be divided into volatile materials and nonvolatile materials. In addition, inlet air rapidly and repeatedly swirls upward and downward in the incinerator, and so combustion gases are completely burned up in the incinerator before they are exhausted from the incinerator. Therefore, exhaust gas discharged from the internal exhaust tub 90 of the incinerator is exhaust gas free from smoke, odor or color. During the incineration of wastes in the incinerator of this invention, dust- laden air is guided from the external lower tub 30 into the dust collecting tub 40 through the dust guide pipe 43 connecting the dust collecting port 32 of the external lower tub 30 to the dust collecting tub 40, and so dust is removed from the air before the air is discharged from the incinerator. In such a case, the dust collecting port 32 is formed on the external lower tub 30 such that the port 32 is directed opposite to the swirling direction of the inlet air in the tub 30. The dust- laden air rapidly swirls along with the inlet air in the tub 30 prior to flowing into the dust guide pipe 43 through the dust collecting port 32.
The air laden with dust, flowing into the dust guide pipe 43 through the dust collecting port, is fed to the lower portion of the dust collecting tub 40. hi the dust collecting tub 40, heavy dust and impurities are collected in the lower portion of the tub 40 around the dust guide tube 44, and air is discharged from the tub 40 through the dust outlet ports 42 after being filtered by the air filter 46.
When dust and impurities are collected in the lower portion of the dust
collecting tub 40, a user checks the quantity of dust and impurities through a transparent window (not shown) formed at the sidewall of the tub 40 to determine whether the tub 40 must be emptied or not. When it is desired to empty the dust collecting tub 40, the user removes the tub 40 from the dust collecting tub support member 41, and empties the tub 40 prior to setting the tub 40 on the support member 41.
In addition, when it is desired to measure the components of the exhaust gas discharged from the incinerator "A" and/or the operational temperature of the incinerator, the user goes up on a measuring tower 170 installed at a side of the incinerator "A", and installs an exhaust gas sensor (not shown) in the exhaust gas sensor holder 89 and/or a temperature sensor 67a in the second sensor fitting hole 86. The user measures the components of the exhaust gas of the incinerator "A" using the exhaust gas sensor (not shown) so as to appropriately control the exhaust gas such that the harmful contents of the exhaust gas do not exceed allowable levels, hi addition, the user appropriately controls the operational conditions of the incinerator "A" by checking the operational temperature of the incinerator using the temperature sensor 67a.
During the incineration of wastes in the incinerator "A", fuel is sprayed onto the wastes from the nozzles 112 and 122 of the two fuel inlet pipes 110 and 120 set in the upper and lower portions inside the internal lower tub 10 under the condition that flame of the wastes is continuously stabilized by the flame stabilizer 130. In such a case, the user appropriately controls the spraying of fuel onto the wastes to accomplish complete combustion of the wastes while viewing the interior of the internal lower tub 10 through the window 34a of the slidable ash outlet door 34.
Industrial Applicability
As described above, the present invention provides a high temperature gas
reforming cyclo-incinerator used for burning up combustible wastes. This incinerator has an air cooling structure designed to strongly swirl inlet air in the incinerator prior to discharging the air from the incinerator, thus lengthening circulation time of the inlet air in the incinerator. The incinerator also has a heat shielding structure using a heat shielding plate, designed to prevent heat dissipation from the external surface of the incinerator and protect a user from being burned by dissipated heat. This incinerator also keeps a fire alive until wastes in the incinerator are completely burned up, feeds fuel to completely burn up incompletely burned wastes, and collects and temporarily stores dust-laden air generated from the combustion of the wastes prior to filtering the air to remove dust from the air and discharging clean air to the atmosphere. The incinerator of this invention is preferably used for burning up a variety of combustible wastes, such as domestic refuses, waste plastics, waste rubber, waste food, waste tires, medical refuses, waste oil, and livestock wastes, which are not recyclable. This incinerator almost completely burns up the wastes through pyrolysis using very high temperature heat of about 1800 °C, thus accomplishing complete combustion of the wastes without generating smoke or odor and thereby almost completely removing harmful gases, such as carbon monoxides, nitrogen oxides, or sooty smoke, from its exhaust gas.