JP4579944B2 - Exhaust gas treatment equipment - Google Patents

Description

The present invention relates to an exhaust gas treatment apparatus that easily generates dust in the case of combustion treatment. For example, in order to combust a harmful flammable or hardly decomposable exhaust gas containing silane gas (SiH ₄ ) or halogen-based gas (NF ₃ , ClF ₃ , SF ₆ , CHF ₃ , C ₂ F ₆ , CF _4, etc.) The present invention relates to a combustion type exhaust gas treatment apparatus.

Exhaust gas that easily generates dust when subjected to combustion treatment includes harmful flammable gases such as silane (SiH ₄ ) and disilane (Si ₂ H ₆ ) from semiconductor manufacturing apparatuses and liquid crystal panel manufacturing apparatuses. In addition, although there are gases containing persistent warming gases (PFCs), these exhaust gases cannot be released into the atmosphere as they are because they adversely affect the human body or the global environment changes. Therefore, in general, these exhaust gases are led to a detoxifying device and subjected to oxidation detoxification treatment by combustion. As this processing method, a method is used in which a flame is formed in a furnace using an auxiliary combustion gas and the exhaust gas is burned by this flame.

  In such a combustion type exhaust gas treatment apparatus, hydrogen, city gas, LPG or the like is used as a fuel gas as a combustion gas, and oxygen or air is usually used as an oxidant. Costs associated with consumption of combustion gases and oxidants account for the majority. Thus, how much harmful exhaust gas is decomposed with high efficiency by a small amount of auxiliary combustion gas is one of the measures for evaluating the performance of this type of apparatus.

  27 and 28 show a general configuration of a combustor used in the conventional combustion type exhaust gas treatment apparatus. This includes a burner unit 101 and a combustion reaction unit (combustion chamber) 102 that heat-oxidizes and decomposes exhaust gas at a subsequent stage of the burner unit 101. The burner unit 101 has an exhaust gas nozzle 103 for introducing the exhaust gas G1 to be processed into the combustion reaction unit 102 opened at the center of the ceiling of the combustion reaction unit 102, and an exhaust gas nozzle 103 that is opened at the outer periphery of the exhaust gas nozzle 103. A plurality of auxiliary combustion gas nozzles 104 for introducing the auxiliary combustion gas G <b> 2 into the part 102. A combustion gas outlet 105 is integrally connected to the lower end of the combustion reaction part 102. As a result, the exhaust gas G1 is passed through the center portion of the flame formed in a ring by the auxiliary combustion gas G2 ejected from the auxiliary combustion gas nozzle 104, and the exhaust gas G1 is mixed with the flame and burned during this passage. Thus, the combustion gas after combustion is discharged from the combustion gas outlet 105 to the outside.

  Here, the combustion reaction section 102 is generally defined by an inner wall surface 106a of a cylindrical furnace body 106 made of a metal such as stainless steel, and the outer peripheral surface of the furnace body 106 is shielded from heat as necessary. Insulating material for the installation or water cooling structure was adopted.

  On the other hand, as a method for decomposing a fluorocarbon-based gas, which is currently a cause of global warming, a thermal decomposition method in a high temperature environment or decomposition in plasma has become the mainstream. In order to use these methods, in a decomposition treatment facility equipped with a complicated control mechanism for controlling a heating device such as a heater, a plasma generation device, a safety device, etc., a huge amount of energy is applied to generate a heated plasma and fluorocarbon. The gas of the system is decomposed.

  However, in the conventional example shown in FIGS. 27 and 28, the combustion reaction section 102 is constituted by a metal furnace body 106, and is exposed to a high temperature atmosphere of 1300 ° C. or higher when a combustion flame is formed (during operation). As a result, the furnace body 106 was consumed very much and could not withstand long-time operation. In particular, when the halogen-based gas is decomposed by this apparatus, the furnace body is subjected to etching and corrosion at high temperatures by the generated halogen gas (HCl, HF, etc.) after the processing reaction, and is exhausted violently.

  When the furnace body 106 is consumed in a short time as described above, it is necessary to frequently replace the furnace body 106, resulting in an increase in equipment cost. Furthermore, if the metal furnace body is worn out, there is a risk that the surrounding structure (insulation material, water-cooled container, etc.) will wear out. Therefore, it is necessary to frequently disassemble and inspect the furnace body as a facility. The operating rate is significantly reduced, and the operating cost is increased.

  Furthermore, since the inner wall surface of the metal furnace body 106 is heated to a high temperature by the combustion flame in the combustion reaction section 102, the generation of thermal NOx is promoted by the catalytic effect of the metal. For example, this type of exhaust gas combustion equipment in semiconductor industrial equipment is generally premised on installation in a clean room, and it is necessary to reduce the size of the equipment. However, if a large amount of NOx is produced, it is processed. Therefore, it is necessary to separately provide a dedicated processing mechanism, and as a result, it cannot be reduced in size.

  Further, in the combustor that forms a combustion flame as described above, a flame is formed at the lower end of the burner portion 101. As a result, the temperature in the vicinity of the opening of the burner portion 101 made of stainless steel or the like rises, and the burner portion 101 There was a risk that the supplied auxiliary combustion gas G2 would ignite and explode.

Further, there is a gas that generates dust such as SiO _{2 when} detoxified by a heat decomposition type exhaust gas treatment apparatus, such as SiH ₄ used in a semiconductor device manufacturing process, particularly a CVD process. There is a problem that such dust flows together with exhaust gas and adheres to the inner wall surface of piping and the like, and increases exhaust pressure loss. As a method for preventing the dust from adhering to the inner wall surface of the pipe or the like, conventionally, a cleaning gas blow-off method, an intermittent manual scraping device scraping method, and dust adhering by constantly flowing a cleaning gas from the porous inner wall are used. There was a way to prevent it.

  The cleaning gas blowing method is a method in which fixed nozzles are provided in the entire circumferential direction of a pipe, and cleaning gas is ejected constantly or intermittently to remove dust. This method has a problem that the dust removal effect is lowered when the nozzle is located away from the dust adhesion position. If a large amount of cleaning gas is flowed so that the effect is not lowered, the cost of the cleaning gas itself is increased. In addition, there is a problem that the piping must be thickened to reduce pressure loss due to a large amount of gas flowing.

  Since the scraping method using the intermittent manual scraping device is to scrape after the dust has grown greatly, a tank for storing a large lump of dust scraped is necessary.

  In addition, in the prevention of adhesion by constantly flowing the cleaning gas from the porous inner wall, a large amount of cleaning gas must be flowed to maintain the flow rate of the cleaning gas from the inner wall throughout the pipe in order to prevent dust adhesion. In order to reduce pressure loss due to a large amount of gas flow, there is a problem that the pipe must be thickened.

  In addition, there is a problem that the cost of the cleaning gas itself is increased, and facilities such as a duct for exhausting the gas discharged from the abatement apparatus from the inside of the building to the outside of the building must be enlarged.

  The present invention has been made in view of the above circumstances, and suppresses the consumption of the inner wall constituting the combustion reaction part exposed to high temperatures to improve the life, improve the equipment cost and operation efficiency, and suppress the generation of NOx. It is an object of the present invention to provide an exhaust gas treatment device that can be used.

  It is another object of the present invention to provide an exhaust gas treatment apparatus that suppresses an increase in temperature due to a flame near the opening of a combustion burner and has no danger of explosion of an auxiliary combustion gas.

  Another object of the present invention is to provide an exhaust gas treatment apparatus that can reliably remove dust adhering to the inner wall surface of a pipe and that requires a small amount of cleaning gas even when cleaning gas is injected.

The present invention includes a burner portion, and a combustion chamber provided on the downstream side of the burner portion, the combustion flame is formed toward the combustion chamber from the burner unit, by introducing the exhaust gas to the combustion flame, the In the exhaust gas treatment apparatus for oxidizing and decomposing exhaust gas, the burner part includes a cylindrical body whose top is closed and whose lower part is open, and an exhaust gas inlet is provided at the top of the cylindrical body, and air is provided at a predetermined position on the side wall. A nozzle is provided, an auxiliary gas nozzle is provided on the side wall near the opening, the exhaust gas introduced from the exhaust gas inlet and the air blown from the air nozzle are mixed, and the auxiliary gas blown from the auxiliary nozzle is ignited. A combustion flame is formed toward the lower side of the opening, and a cooling means for cooling an auxiliary combustion gas introduction part for introducing a fuel gas to the auxiliary combustion gas nozzle is provided, and the auxiliary combustion gas introduction part is provided outside the cylindrical body. An auxiliary combustion gas chamber or auxiliary combustion gas introduction pipe provided on the side, the auxiliary combustion gas nozzle is provided at the tip of the auxiliary combustion gas chamber or auxiliary combustion gas introduction pipe so as to blow out the auxiliary combustion gas toward the combustion chamber, and the cooling means A cooling medium was supplied to a cooling jacket provided adjacent to the auxiliary combustion gas chamber or the auxiliary combustion gas introduction pipe to cool the auxiliary combustion gas chamber or the auxiliary combustion gas introduction pipe. As a result, even if the auxiliary combustion gas introduction part is heated by the flame, the temperature rise is suppressed below the ignition point of the auxiliary combustion gas, thereby eliminating the risk of explosion of the auxiliary combustion gas.

  Further, in the exhaust gas treatment device, dust removal means for removing dust attached to the burner part and / or the combustion chamber wall or preventing dust from being attached is provided, and the exhaust gas treatment device can be operated for a long time.

  A dust removing device for removing dust adhering to an inner wall of a pipe through which a gas body containing a large amount of dust flows, and a scraping mechanism having a configuration in which a rod-shaped scraping member disposed in the pipe and extending in the longitudinal direction of the pipe is attached to the main shaft. A supporting mechanism for supporting the scraping member so that the scraping member contacts the inner surface of the pipe or moves in the inner circumferential direction with a small interval; and the scraping mechanism is continuously or periodically centered on the spindle. And a drive mechanism that swings or rotates. Therefore, by blowing the cleaning gas from the outside of the pipe through the main shaft and the hollow of the scraping member and blowing out the cleaning gas from the tip of the scraping member or the numerous holes or slits on the surface, dust in the pipe that the scraping member does not reach can only be removed. In addition, it is possible to remove dust adhering to the scraping mechanism itself.

  In the exhaust gas treatment apparatus, the burner portion includes a cylindrical body whose top portion is closed and whose lower portion is opened, and an exhaust gas inlet is provided at the top portion of the cylindrical body, and an air nozzle is provided at a predetermined position on the side wall. An auxiliary gas nozzle is provided on the side wall in the vicinity of the opening, and the air nozzle promotes the ignition of the auxiliary gas injected from the auxiliary nozzle, and the swirling airflow is blown downward to the combustion flame formed toward the lower part of the opening. Since it comprised, dust becomes difficult to adhere to a burner part inner wall.

  Further, in the exhaust gas treatment apparatus, the burner portion includes a cylindrical body whose top is closed and whose lower portion is open, and an exhaust gas inlet is provided at the top of the cylindrical body, and an air nozzle is provided at a predetermined position on the side wall. A combustion gas nozzle is provided on the side wall in the vicinity of the opening, and the exhaust gas inlet and the inner diameter of the cylindrical body gradually increase toward the combustion chamber. As a result, there is no right-angled corner in the burner and dust is less likely to adhere to the inner wall of the nozzle.

  Further, an exhaust gas treatment apparatus is configured by integrally providing a burner portion, a combustion chamber provided on the downstream side of the burner portion, and a combustion gas cooling portion provided on the downstream side of the combustion chamber. An exhaust gas inlet for introducing exhaust gas and an air nozzle for introducing swirl flow by introducing air are provided, and the combustion gas cooling unit cools the exhaust gas flowing from the combustion chamber and captures dust in the exhaust gas. A liquid spray nozzle for spraying liquid, an exhaust pipe for discharging the exhaust gas, and a drain pipe for discharging the liquid sprayed by the liquid spray nozzle were provided. By configuring the exhaust gas treatment device in this way, it is possible to efficiently capture and absorb the dust, HCl, and HF in the exhaust gas introduced from the exhaust gas inlet into the liquid sprayed from the spray nozzle. it can.

  1 and 2 are views showing a configuration of an exhaust gas combustor of an exhaust gas treatment apparatus according to the present invention, FIG. 1 is a longitudinal sectional view, and FIG. 2 is a sectional view taken along line II in FIG. The exhaust gas combustor is configured as a cylindrical sealed container as a whole, and includes an upper burner unit 10 and a middle combustion chamber (combustion reaction unit) 30, and includes a cooling unit 51 and a discharge unit 52 in the lower stage. ing. As the cooling medium of the cooling unit 51, for example, a liquid such as water or a gas such as air is used.

The burner portion 10 includes a cylindrical body 11 that forms a flame holding portion 18 that opens toward the combustion chamber 30, and an outer cylinder 12 that surrounds the cylindrical body 11 at a predetermined interval. Between the body 11 and the outer cylinder 12, an air chamber 19 for holding combustion air and an auxiliary combustion gas chamber 20 for holding auxiliary combustion gas such as a premixed gas of hydrogen and oxygen are formed. These air chamber 19 and auxiliary combustion gas chamber 20 communicate with an air source and a gas source (not shown). Here, hydrogen, propane, city gas, or the like is used as the auxiliary combustion gas. Connected to the top of the cylindrical body 11 that covers the upper side of the flame holding section 18 is an exhaust gas introduction pipe 14 that introduces an exhaust gas G1 containing, for example, silane (SiH ₄ ) discharged from a semiconductor manufacturing apparatus into the flame holding section 18. Yes.

  The cylindrical body 11 is provided with a plurality of air nozzles 15 communicating with the air chamber 19 and the flame holding portion 18 and a plurality of auxiliary combustion gas nozzles 16 communicating with the auxiliary combustion gas chamber 20 and the flame holding portion 18. As shown in FIG. 2, the air nozzle 15 extends at a predetermined angle with respect to the tangential direction of the cylindrical body 11, and blows out air so as to form a swirling flow in the flame holding portion 18. Similarly, the auxiliary combustion gas nozzle 16 extends at a predetermined angle with respect to the tangential direction of the cylindrical body 11, and the auxiliary combustion gas is blown out so as to form a swirling flow in the flame holding portion 18. The air nozzle 15 and the auxiliary combustion gas nozzle 16 are equally arranged in the circumferential direction of the cylindrical body 11.

  A secondary air chamber 31 is formed around the boundary between the flame holding section 18 and the combustion chamber 30 so as to surround the opening of the flame holding section 18, and the secondary air chamber supplies secondary air. For communication with an air source (not shown). Secondary air nozzles 33 for blowing secondary air for oxidizing exhaust gas into the combustion chamber 30 are equally arranged in the circumferential direction on the partition plate 32 that partitions the secondary air chamber 31 and the auxiliary combustion chamber 30. Is provided.

  The combustion chamber 30 is a space for oxidizing and decomposing exhaust gas at the subsequent stage of the burner unit 10, and is disposed inside the airtight cylindrical outer container 34 made of metal or the like so as to be continuous with the flame holding unit 18. A partition is formed by a cylindrical inner wall 35. As will be described later, the inner wall 35 is formed of fiber reinforced ceramic. A heat insulating material 37 made of porous ceramic is inserted into a space 36 between the inner wall 35 and the outer container 34. A purge air introduction pipe 40 for introducing purge air into the space 36 is connected to the outer container 34.

  The fiber reinforced ceramic constituting the inner wall 35 is made by weaving a fiber formed of ceramics into a cloth, applying a ceramic containing a binder thereto, forming this into a cylindrical shape, and solidifying it. Laminate the sheets. Thus, mechanical strength and high temperature strength can be improved by reinforcing the ceramic itself with ceramic fibers. As a result, even when the inner wall 35 is exposed to a high temperature during combustion and thermal stress acts, the occurrence of cracks can be reduced. Further, etching and corrosion are not easily caused by a corrosive gas such as a halogen gas generated by the combustion process. Therefore, a long service life can be obtained. On the other hand, the heat insulating material 37 made of porous ceramic can be formed by forming fibers with ceramics and forming them with a molded suction device so as to be adapted to the shape of the space 36.

  Examples of the ceramic material for the heat insulating material 37 and the inner wall 35 include alumina having a purity of 80 to 99.7% and Si-based materials. In the case of treating a gas containing fluorine, it is desirable to use alumina having high corrosion resistance against the exhaust gas. When an alumina continuous fiber is used as the fiber reinforced ceramic for the inner wall 35, it has high heat resistance, wind speed resistance, and wear resistance, and can withstand a large thermal shock and temperature gradient.

The combustion chamber 30 is provided with a UV sensor 38 for detecting a flame and a pilot burner 39 for igniting the burner unit 10. The UV sensor 38 and the pilot burner 39 may be attached to the top of the cylindrical body 11 (the top plate of the burner unit 10) as shown in FIG. The UV sensor 34 is disposed to be inclined with respect to the top of the cylindrical body 11 in order to detect the formed flame from an oblique direction. This is because the flame forms a swirling flow in the combustion chamber 30 and the flame becomes shorter in the radial direction. When silane (SiH ₄ ) or the like is treated, the SiO ₂ dust adheres to the inner wall surface of the combustion chamber 30 and the UV sensor 38 cannot detect a flame. In this way, the UV sensor 38 is attached to the top plate of the burner unit 10. As a result, it is possible to avoid the problem that the flame cannot be detected due to dust adhesion. In addition, in order to treat the hardly decomposable global warming gases (PFCs), a high temperature of 1300 ° C. or higher is required, so that the pipe is corroded by heat. By attaching to the top plate of the burner unit 10, such corrosion due to high heat can be avoided.

  At the lower part of the combustion chamber 30, a discharge part 52 is provided via a cooling part 51 to be cooled. The cooling unit 51 has a plurality of nozzles 53 provided at equal intervals in the circumferential direction at the lower edge, and a water curtain is formed by injecting water from the nozzles 53 toward the center, thereby Cooling and trapping of particles in the exhaust gas are performed. An exhaust pipe 54 for exhausting the treated exhaust gas is provided on the side wall of the discharge part 52, and a drain port 55 for discharging the water sprayed from the nozzle 53 is provided on the bottom part.

  Next, the operation of the exhaust gas treatment apparatus of the above embodiment will be described. First, the auxiliary combustion gas is guided and held in the auxiliary combustion gas chamber 20 and blown out from the auxiliary combustion gas nozzle 16 provided on the inner peripheral surface of the cylindrical body (inner cylinder) 11 to create a swirling flow toward the flame holding portion 18. Is done. When ignited by the pilot burner 39, a swirling flame is formed on the inner peripheral surface of the cylindrical body (inner cylinder) 11.

  Here, the auxiliary combustion gas forms a swirling flame, but the swirling flame has a characteristic that it can be stably burned over a wide range of equivalent ratios. That is, since it is swirling strongly, heat and radicals are supplied to each other, and the flame holding property is enhanced. For this reason, normally, unburned gas is not generated even at a small equivalent ratio that generates or extinguishes unburned gas, and stable combustion without inducing vibration combustion even in the vicinity of equivalent ratio 1 Can be made.

  On the other hand, the exhaust gas G <b> 1 to be treated is ejected from the exhaust gas introduction pipe 14 that opens to the lower surface of the top of the cylindrical body 11 toward the flame holding section 18. The ejected exhaust gas G1 is mixed with the swirling flow of the auxiliary combustion gas and combusted. At this time, the auxiliary combustion gas is blown out so as to strongly swirl in one direction downstream from all the auxiliary combustion nozzles in the circumferential direction. All of the auxiliary combustion gas is sufficiently mixed with the flame, and the combustion efficiency of the exhaust gas becomes very high.

  Further, if the auxiliary combustion gas is overheated to a temperature exceeding its ignition temperature, if the auxiliary combustion gas contains an oxidizer, combustion may start in the auxiliary combustion gas chamber 20, so that the ignition temperature is reduced. It is necessary to cool so as not to exceed. Furthermore, it has been found by the inventors' research that the swirling flame heats the auxiliary combustion gas in the cylindrical body 11 and the auxiliary combustion gas chamber 20. Therefore, in order to continue stable combustion, it is necessary to cool the cylindrical body 11 so as not to exceed the heat resistance temperature of the constituent material. The swirling air flow injected from the air spill 15 to the retaining flame part 18 has the effect of cooling the auxiliary combustion gas chamber 20.

  Furthermore, although the flame from the auxiliary combustion gas nozzle 16 is swirled and jetted, the air jetted from the air nozzle 15 is also swirling, and this air flow is mixed with the flame to further accelerate the swirl flow of the flame. A strong swirl flow. When the swirl flame is formed, the pressure of the airflow at the center of the swirl decreases, and a self-circulating flow that flows backward from the front of the flame toward the exhaust gas introduction pipe 14 and the auxiliary combustion gas nozzle 10 is generated at the center. Mixing with the flame and combustion gas from the auxiliary combustion gas nozzle 16 suppresses the generation of NOx. Alternatively, low NOx combustion is possible even when a premixed gas is used as the auxiliary combustion gas and the equivalent ratio of the auxiliary combustion gas is reduced.

In addition, since the flame from the auxiliary gas nozzle 16 swirls strongly, when this swirling flow is directed to a gas that generates dust by combustion, such as silane gas, silica (SiO ₂ ) generated by combustion is generated. It acts to prevent adhesion to the exhaust gas introduction pipe 14 and the auxiliary combustion gas nozzle 16. That is, when silane (SiH ₄ ) or the like is combusted, powdered silica (SiO ₂ ) is generated. If this silica (SiO ₂ ) adheres to the vicinity of the exhaust gas introduction pipe 14 or the auxiliary combustion gas nozzle 16, the auxiliary combustion gas The blowout may become unstable by reducing the ejection amount or changing the ejection direction. In such a situation, the gas blowing is not settled and stable combustion becomes impossible.

In the present embodiment, since there is a swirling flame of the auxiliary combustion gas nozzle 16, a fast flow is generated in the exhaust gas introduction pipe 14 and the tip of the auxiliary combustion gas nozzle 16 by this swirling flame, and this flow is the exhaust gas introduction pipe 14. It also acts to clean the tip of the auxiliary gas nozzle 16 and to prevent the generated powdered silica (SiO ₂ ) from adhering to the exhaust gas introduction pipe 14 and the tip of the auxiliary gas nozzle 16. This effect becomes even more remarkable due to the swirling air flow from the air injection nozzle 15.

Further, this effect is not limited to the exhaust gas introduction pipe 14 and the tip of the auxiliary combustion gas nozzle 16. That is, since the flame swirls inside the combustion chamber 30, a fast flow is generated on the wall surface of the combustion chamber 30 to clean the wall of the combustion chamber 30, and silica (SiO ₂ ) adhering to this surface is cleaned. It works to remove. Thus, the swirling flow, silica adhering to the wall surface of the tip and combustion chamber 30 of the exhaust gas inlet pipe 14 and the burner air nozzles 16 by self-cleaning the (SiO _2), silica attached to the surface (SiO ₂₎ It works to remove.

  As an example, the fuel-rich premixed fuel is supplied with a premixed gas containing oxidizer and the mixture ratio of oxidizer to combustion gas in the premixed gas is less than the stoichiometric value. This is swirled and injected from the auxiliary combustion gas nozzle 16 to form a primary swirling flow reducing flame inside the heat retaining section 18. The reducing flame is brought into contact with the exhaust gas from the exhaust gas introduction pipe 14 to reduce and decompose exhaust gas, particularly PFCs-based exhaust gas.

  Next, sufficient oxygen equal to or higher than the stoichiometric value is given from the air injected from the air nozzle 15 and the secondary air nozzle 33, and a secondary oxidation flame is formed in an oxygen-excess state. The exhaust gas is oxidatively decomposed by this oxidation flame. The exhaust gas is exposed to a two-stage flame of a reducing flame and an oxidizing flame, and the contact time with the flame can be lengthened to extend the high temperature residence time. Here, the PFCs-based exhaust gas has a characteristic that it can be decomposed by increasing the ambient temperature and maintaining the state for a long time. In this way, the exhaust gas is exposed to a two-stage flame with different oxidation and reduction, and by extending the high temperature state due to the flame, the exhaust gas, particularly PFCs-based gas, can be completely decomposed.

  Since the auxiliary combustion gas nozzle 16 is configured to blow off the auxiliary combustion gas while forming a swirling flow toward the obliquely downstream side of the flame holding portion 18, the flame blown out from the auxiliary combustion gas nozzle 16 spirally turns toward the downstream side of the flame holding portion 18. Form a flow. Therefore, the swirl length when the swirling flow flows inside the cylindrical body 11 is shorter than that when the auxiliary combustion gas is blown horizontally, and the region in which the flame heats the inner wall surface of the cylindrical body 11 is narrowed. Heating and temperature rise of the inner peripheral wall of the cylindrical body 11 are suppressed.

  Thereby, the heat-resistant life of the constituent material of the cylindrical body 11 can be extended. In addition, the amount of cooling air from the air nozzle 15 can be reduced, the temperature drop of the flame due to cooling can be suppressed, the high temperature state can be maintained, and the decomposition efficiency of the exhaust gas containing halogen-based, particularly fluorocarbon, can be improved. Further, when viewed from above, the auxiliary gas nozzle 16 may be provided in a plural number so as to open in the tangential direction of the cylindrical body 11 and open obliquely downward in the vertical plane. It is possible to form a spiral swirl toward the head.

Further, in the present embodiment, the secondary air nozzle 33 is directed downward, but may be ejected toward the center of the cylindrical body 11, and the secondary air nozzle 33 is ejected from the nozzle. It is also conceivable to provide the air to be swirled in the combustion chamber. Accordingly, it is possible to more effectively perform the gas cooling after the combustion treatment, the discharge to the outside of the combustion chamber 30, and the removal of silica (SiO ₂ ) adhering to the wall surface of the combustion chamber 30. In this case, the nozzle is provided in the same manner as the auxiliary gas nozzle 16 described above.

  Further, by providing an air injection nozzle at the top of the cylindrical body 11 and supplying air from the air injection nozzle to the flame holding portion 18 as necessary to increase the oxygen concentration, the combustibility can be improved.

  Further, the peripheral wall of the flame holding section 18 downstream from the auxiliary combustion gas nozzle 16 is extended to further provide air holes for secondary combustion, and the flame holding section 18 has a reducing flame for primary combustion and an oxidation flame for secondary combustion using air. Thus, it is possible to improve the decomposition rate of the gas containing the exhaust gas G1, especially the halogen-based gas, particularly the fluorocarbon. In this case, for the reason described above, it is preferable to inject the air holes toward the flame holding portion 18 so as to form a swirling flow. Moreover, it injects toward the center direction of the cylindrical body 11, and it may be made to disturb and mix with the exhaust gas after the primary combustion by a reducing flame.

  Moreover, although the example which blows out a flame from upper direction is shown, you may apply to the flame made to blow out in a horizontal direction. The auxiliary combustion gas is not limited to a premixed gas of hydrogen and oxygen, but is a fuel gas such as hydrogen, city gas and LPG, or a premixed gas of city gas, LPG and oxygen, air or oxygen-enriched air. Of course.

  An example is as follows.

Target gas; CF ₄
As reductive decomposition reaction in the reducing flame,
CF ₄ + H ₂ → CHmFn + HF + F ₂ (m and n are 0 to 4)
Furthermore, as an oxidative decomposition reaction,
CHmFn + O ₂ → CO ₂ + H ₂ O
In the combustion chamber 30, the ceramics constituting the inner wall are excellent in heat resistance and corrosion resistance, and are not only less consumed by heat and corrosion, but also are reinforced to fibers and prevent cracking due to thermal stress. Can be used across. And since there is no catalytic effect like the case of a metal, generation | occurrence | production of thermal NOx is suppressed even if the combustion chamber 30 becomes high temperature. Even when the halogen-based gas is decomposed, corrosion or etching of the inner wall 35 at a high temperature due to the halogen gas (HCl, HF, etc.) generated therewith is suppressed.

  In particular, when using fiber-reinforced ceramics made of alumina, the thermal conductivity under normal operating conditions (600-1300 ° C.) is about 0.65-0.88 (W / m.K). Yes, it is several hundred times higher than the average thermal conductivity of stainless steel metal = 0.0017 (W / m.K). Therefore, cracks due to thermal stress are further reduced. Moreover, since the heat insulating material 37 made of porous ceramics is disposed on the outer periphery of the inner wall 35, the amount of heat loss can be further reduced as compared with the case of using a conventional inner wall made of stainless steel metal. This is the same even when other ceramics such as Si are used.

  From the purge air introduction pipe 40, purge air is introduced into the space 36 between the outer container 34 and the inner wall 35 at a pressure slightly higher than the pressure in the combustion chamber 12. This air is jetted into the combustion chamber 30 through the inner wall 35 and a minute gap at the end thereof, mixed with the combustion gas and exhaust gas, and discharged from the discharge portion 52 to the outside. Thereby, harmful and corrosive gas in the combustion chamber 30 can be prevented from leaking from the outer container 34 to the outside.

  In addition, as described above, the inner wall 35 of the combustion chamber 30 is made of ceramics, thereby preventing the catalytic action and reducing NOx. Furthermore, if the equivalent ratio of the auxiliary combustion gas is reduced, further low NOx combustion becomes possible.

  The results of comparing the amount of NOx produced in the case of the combustor using the ceramic inner wall with that of the combustor using the stainless steel inner wall are shown below. The conditions such as the combustor type are the same in both cases.

Combustion temperature: 1300 ° C or higher Processed gas: N ₂ gas Exhaust gas NOx concentration Ceramic inner wall: 25 ppm
Stainless steel inner wall: several hundred to several thousand ppm
3 and 4 are views showing another configuration example of the burner part of the exhaust gas treatment apparatus of the present invention, FIG. 3 is a longitudinal sectional view, and FIG. 4 is an arrow A view of FIG. In the same figure, the part which attached | subjected the same code | symbol as FIG.1 and FIG.2 shows the same or equivalent part. The same applies to other drawings. The burner portion 10 is provided with a cooling jacket 21 adjacent to the auxiliary combustion gas chamber 20 on the outer peripheral portion of the cylindrical body 11. A cooling medium is supplied to the cooling jacket 21. By supplying a cooling medium to the cooling jacket 21, the cooling jacket 21 cools the cylindrical body 11 heated by the flame formed in the opening. The cooling medium has only to have a temperature difference, and a liquid such as water or a gas such as air is used.

  Further, the pilot burner portion 39 is provided on the top portion of the cylindrical body 11 (the top plate of the burner portion 10) so as to be inclined at a predetermined angle. This is because the auxiliary combustion gas (flame) injected from the auxiliary combustion gas nozzle 16 becomes shorter with respect to the radial direction, so the pilot burner should be provided at a predetermined angle.

In the combustion burner section 10 of the combustor shown in FIG. 1, the internal temperature of the cylindrical body 11 has risen to 400 ° C. However, particularly in the case of water cooling, this burner section 10 decreases to 70 ° C. Therefore, there is no danger that the auxiliary combustion gas held in the auxiliary combustion gas chamber 20 will ignite and explode. However, since the secondary air nozzle described above is eliminated, the air is dealt with by increasing the primary air from the air nozzle 15 or increasing the amount of premixed O ₂ . Here, the air nozzle 15 is provided so as to face obliquely downward, and a swirling air flow is formed obliquely below. However, the air nozzle 15 is provided horizontally as shown in FIG. Of course, a flow may be formed.

As described above, by the burner unit 10 and the cooling structure, the temperature of the cylinder 11 is reduced, C _{2 F} 6 _(This gas 10 global warming potential of CO ₂ is persistent gas, 000 times, and 100% decomposition is required as a measure against global warming), the processing capacity has dropped from 80% to 41%. This is considered because the temperature of the burner part 10 falls and the fall of the flame temperature has influenced by it. Therefore, the configuration of the burner part that can effectively cool the fuel gas introduction part that introduces the auxiliary combustion gas into the auxiliary combustion gas nozzle 16 that is heated and has a risk of explosion will be described below.

  5 and 6 are views showing another example of the structure of the burner part of the exhaust gas treatment apparatus according to the present invention, FIG. 5 is a longitudinal sectional view, and FIG. The burner portion 10 is provided with an air chamber 22 on the upper outer periphery of the cylindrical body 11, and further provided with a cooling jacket 24, an auxiliary combustion gas chamber 23, and a cooling jacket 24 on the lower outer periphery. An air nozzle 15 communicating with the air chamber 22 is provided on the inner peripheral wall of the cylindrical body 11, and an auxiliary combustion gas nozzle 16 communicating with the auxiliary combustion gas chamber 23 is provided on the lower surface of the auxiliary combustion gas chamber 23.

  As indicated by an arrow B, the auxiliary gas from the auxiliary gas nozzle 16 is injected toward the central portion below the opening of the cylindrical body 11 or obliquely downward so as to form a swirling flow. Further, the air injected from the air nozzle 15 becomes a swirl flow swirling in the cylindrical body 11 as indicated by an arrow C.

  In the burner unit 10 having the above-described configuration, the processing gas G1 introduced into the cylindrical body 11 is mixed with the swirling air flow from the air nozzle 15 and the auxiliary combustion gas injected below the burner unit 10 from the auxiliary combustion gas nozzle 16. After mixing, a flame is formed toward the lower part of the opening of the cylindrical body 11 by ignition. At this time, the auxiliary combustion gas chamber 23 is cooled by the cooling jacket 24 from both sides, and the temperature is kept low. Further, since the flame is formed downward from the cylindrical body 11, the temperature drop of the cylindrical body 11 does not greatly affect the flame.

  7 and 8 are views showing another example of the structure of the burner part of the exhaust gas treatment apparatus according to the present invention, FIG. 7 is a longitudinal sectional view, and FIG. 8 is an E view of FIG. The burner unit 10 differs from the burner unit 10 shown in FIGS. 5 and 6 in that an auxiliary combustion gas chamber 23 is provided in a cooling jacket 24 provided on the outer periphery of the cylindrical body 11, and a cooling medium is provided around the auxiliary combustion gas chamber 23. Enclosed in An auxiliary combustion gas nozzle 16 communicating with the auxiliary combustion gas chamber 23 is provided on the lower surface of the auxiliary combustion gas chamber 23.

  As indicated by an arrow B, the auxiliary combustion gas from the auxiliary gas nozzle 16 is injected toward the central portion below the opening of the cylindrical body 11 or obliquely downward and in a swirling manner, and from the air nozzle 15. As shown by an arrow C, the air to be swirled in the cylindrical body 11 is the same as the burner unit 10 shown in FIGS.

  In the burner unit 10 having the above-described configuration, the exhaust gas G1 to be processed introduced into the cylindrical body 11 is mixed with the swirling air flow from the air nozzle, and the auxiliary combustion gas injected from the auxiliary combustion gas nozzle 16 to the lower side of the burner unit 10. The flame is formed toward the lower part of the opening of the cylindrical body 11 by ignition. At this time, since the auxiliary combustion gas chamber 23 is surrounded by the cooling medium in the cooling jacket 24, the auxiliary combustion gas chamber 23 is cooled and the temperature is kept low. Further, since the flame is formed downward from the cylindrical body 11, the temperature drop of the cylindrical body 11 does not have a great influence on the flame as in the burner portion 10 shown in FIGS.

  9 and 10 are diagrams showing another configuration example of the burner part of the exhaust gas treatment apparatus according to the present invention, FIG. 9 is a longitudinal sectional view, and FIG. 10 is an F view of FIG. The burner unit 10 is different from the burner unit 10 shown in FIGS. 5 and 6 in that a cylindrical auxiliary combustion gas chamber 25 is arranged in a cooling jacket 24 formed on the lower outer periphery of the cylindrical body 11. . The cylindrical auxiliary combustion gas chamber 25 is provided with an auxiliary combustion gas nozzle 16 at the tip, and is disposed so as to penetrate the cooling jacket 24 so that the auxiliary combustion gas nozzle 16 is inclined downward.

  As indicated by an arrow B, the auxiliary gas from the auxiliary gas nozzle 16 is injected toward the central portion below the opening of the cylindrical body 11 or obliquely downward and in a swirl flow, and is injected from the air nozzle 15. As shown by the arrow C, the air becomes a swirl flow swirling in the cylindrical body 11 and is substantially the same as the burner unit 10 shown in FIGS.

  In the burner portion having the above-described configuration, the exhaust gas G1 to be treated introduced into the cylindrical body 11 is mixed with the swirling air flow from the air nozzle 15 and fuel gas injected below the burner portion 10 from the auxiliary combustion gas nozzle 16. The flame is formed toward the lower part of the opening of the cylindrical body 11 by ignition. At this time, since the cylindrical auxiliary combustion gas chamber 25 is surrounded by the water in the cooling jacket 24, the cylindrical auxiliary combustion gas chamber 25 is cooled and the temperature is kept low. Further, since the flame is formed downward from the cylindrical body 11, the temperature drop of the cylindrical body 11 does not have a great influence on the flame as in the burner portion 10 shown in FIGS.

  11 and 12 are views showing another example of the structure of the burner part of the exhaust gas treatment apparatus according to the present invention, FIG. 11 is a longitudinal sectional view, and FIG. 12 is an external view of the cooling jacket 26. The burner unit 10 differs from the burner unit 10 shown in FIGS. 5 and 6 in that a cooling jacket 26 is provided on the outer periphery of the lower portion of the cylindrical body 11, and a cylindrical auxiliary combustion gas chamber 27 is disposed in the cooling jacket 26. It is a point. At the tip of the cylindrical auxiliary combustion gas chamber 27, there is provided an auxiliary combustion gas nozzle 16 that is inclined toward the lower side of the opening of the cylindrical body 11 and has a predetermined angle with respect to the tangential direction of the inner peripheral surface.

  As indicated by an arrow B, the auxiliary combustion gas injected from the auxiliary combustion gas nozzle 16 is injected toward the central portion below the opening of the cylindrical body 11 or obliquely downward and in a swirling flow. Moreover, the air injected from the air nozzle 15 swirls into the cylindrical body 11 as in the burner portion 10 shown in FIGS. 5 and 6.

  In the burner unit 10 having the above-described configuration, the processing gas introduced into the cylindrical body 11 is mixed with the swirling air flow from the air nozzle 15 and mixed with the auxiliary combustion gas injected from the auxiliary combustion gas nozzle 16 to the lower side of the burner unit 10. A flame is formed toward the lower side of the opening of the cylindrical body 11 by ignition. At this time, the auxiliary combustion gas chamber 27 is surrounded by the cooling water of the cooling jacket 21, so that it is cooled and the temperature is kept low. Further, since the flame is formed downward from the cylindrical body 11, the temperature drop of the cylindrical body 11 does not significantly affect the flame as in the burner portion 10 of FIGS.

Like exhaust gas containing SiH ₄ or the like, when it is decomposed by heating and detoxified in a combustor, dust such as SiO ₂ is generated, and the dust is generated from the inner wall of the cylindrical body 11 of the burner unit 10, the inner wall of the combustion chamber 30, and the combustion chamber and thereafter There is a gas that adheres to the inner wall of the pipe and causes a problem of increasing exhaust pressure loss. Therefore, the exhaust gas combustor of the exhaust gas processing apparatus of the present invention is provided with a dust removing device for removing dust adhering to the inner wall.

  FIG. 13 is a diagram illustrating a configuration example of a dust removing device. As shown in the figure, the dust removing device is provided with a scraping plate 56 attached to the tip of a shaft 57 that moves up and down across the burner unit 10 and the combustion chamber 30, and the scraping plate 56 is moved up and down to thereby burn the unit. 10 and dust adhering to the inner wall surface of the combustion chamber 30 are scraped off. As shown in FIGS. 14A and 14B, the scraper plate 56 is formed with a circular hole 56 a or a linear hole 56 b that is larger than the opening of the exhaust gas introduction pipe 14. Thereby, when the scraping plate 56 is raised to the uppermost position (the position indicated by the solid line in FIG. 13), the hole 56 a is positioned corresponding to the opening of the exhaust gas introduction pipe 14, and the exhaust gas introduction pipe 14 The flow of exhaust gas flowing into the burner portion 10 (inside the cylindrical body 11) is not hindered. Further, when the scraping plate 56 is raised to the retracted position, the swirling flow of the air blown out from the air nozzle 15 and the auxiliary combustion gas nozzle 16 and the swirling flow of the auxiliary combustion gas are not hindered.

  A cooling receiver 44 is provided at the lower end of the combustion chamber 30 for cooling the exhaust gas burned in the combustion chamber 30 and receiving dust scraped off by the scraping plate 56. A closing valve 45 is attached, and a dust storage tank 47 is attached to the lower end of the closing valve 45 via a clamp 46. The cooling receiver 44 is provided with an exhaust pipe 54 and a drain port 52. Further, a U trap 58 is connected to the dust storage tank 47 via a valve V1, and a drain pipe 59 is connected to the U trap via a valve V2.

  In the dust removing apparatus having the above-described configuration, when it is detected that a predetermined amount of dust has adhered to the burner portion 10 and the inner wall surface of the combustion chamber 30, the shaft 57 is moved up and down manually or automatically, and the scraping plate 56 adheres this dust. The dust thus collected is scraped off to the cooling receiving portion 44. The valve V3 is opened in the cooling receiving portion 44 and dust is collected while draining through the drain port 52. When the dust reaches a predetermined amount, the closing valve 45 is opened and the dust is put into the dust storage tank 47. Then, the closing valve 45 is closed and the valves V1 and V2 are opened to drain the wastewater in the dust storage tank 47 through the drain pipe 59 via the U trap 58. The reason why the U trap 58 is provided here is that when the water is drained directly by the drain pipe 59, harmful gases are also discharged at the same time.

  It should be noted that dust scraping is performed by some means for detecting the amount of dust adhering (for example, a pressure sensor for detecting the pressure of the combustion chamber 30, a temperature sensor for detecting the wall temperature of the combustion chamber 30, and monitoring the amount of dust adhering to the inner wall surface. Monitoring device), and when the amount of adhesion reaches a predetermined amount, the shaft 57 may be automatically moved up and down to scrape dust, or a timer is provided and a predetermined operating time has elapsed. Then, the shaft 57 may be moved up and down to scrape dust. Further, the scraping plate 56 and the like are made of a corrosion-resistant and heat-resistant material such as ceramics.

  Although not shown in the dust storage tank 47, a dust inspection sensor such as a transparent viewing window for confirming the amount of dust accumulated inside, a photoelectric sensor for detecting that a predetermined amount of dust has accumulated, and A water supply pipe for supplying water to the dust storage tank 47 is provided. When a predetermined amount of dust accumulates in the dust storage tank 47, the closing valve 45 is closed and the valves V1 and V2 are opened, and dust is supplied from the water supply pipe. The dust in the dust storage tank 47 may be caused to flow through the U trap 58 by flowing water into the storage tank 47 and flowing dust.

  Further, without providing the drain port 52, the closing valve 45, the valves V1 and V2 are opened, and water and dust are put into the dust storage tank 47 from the cooling unit 44, and the water is drained through the U trap 58. Also good.

  Further, in the configuration example of FIG. 13, the scraping plate 56 moves up and down from the burner unit 10 to the combustion chamber 30, but only the burner unit 10 moves up and down as shown in FIG. Good. Further, the retracted position is not limited to the upper part of the burner unit 10. For example, a drive mechanism for moving the shaft 57 up and down is provided below the combustion chamber 30 or the cooling receiving unit 44, and the retracted position is also at the bottom of the combustion chamber 30. Good.

  FIG. 15 is a diagram illustrating another configuration example of the dust removing device. As shown in the figure, in the dust removing device, a scraping device having a configuration in which a scraping plate 56 is provided at the tip of the shaft 57 as shown in FIG. It is configured to scrape dust adhering to the inner wall due to movement. Further, a ring-shaped air chamber 41 is provided in the upper part of the combustion chamber 30, and a large number of air injection nozzles 42 are provided from the lower surface of the air chamber 41 as shown in FIG. 16. By blowing air from the air injection nozzle 42 downward or obliquely downward along the wall surface of the combustion chamber 30, dust attached to the inner wall surface of the combustion chamber 30 is blown off. In addition, a layer of airflow that flows downward from above is formed, and this airflow layer prevents dust from adhering to the inner wall surface.

  Although not shown in the lower end of the combustion chamber 30, a cooling receiving portion 44 and the like are provided as in FIG. The vertical movement of the shaft 57 is performed manually, automatically, and every elapse of a predetermined operation time by a timer, like the dust removing device of FIG.

  In the above example, the dust adhering to the inner wall of the burner unit 10 is scraped off the shaft 57 with the scraping plate 56, and air is blown along the inner wall surface of the combustion chamber 30 to blow off the adhering dust, or Although an air flow layer is formed to prevent dust adhesion, an air flow layer is formed along the inner wall surface of the burner portion 10 and the combustion chamber 30 to prevent dust adhesion. Good.

  In addition, by intermittently blowing air from the air injection nozzle 42, dust attached to the inner wall surface can be removed with a minimum amount of blowing air.

  17 and 18 are diagrams showing another configuration example of the dust removing device, FIG. 17 is a longitudinal sectional view of the combustion chamber, and FIG. 18 is a sectional view taken along the line III-III in FIG. The inner wall 35 is composed of a porous body (for example, a spherical filter, porous ceramics, a heat-resistant plate material having a large number of pores), and between the inner wall 35 made of the porous body and the outer container 34, respectively. A plurality of independent annular air chambers 36 'are provided. Each air chamber is connected to an air source. By supplying compressed air from the air source, air is uniformly blown into the combustion chamber 30 from the pores of the inner wall 35. By blowing out the air, removal of dust adhered to the inner wall or adhesion of dust to the inner wall 35 is uniformly prevented.

  In the dust removing apparatus having the above configuration, the air (Air) may be continuously blown out from the porous inner wall 35 during the operation of the exhaust gas treatment apparatus. However, in some cases, a predetermined amount of dust adheres to the inner wall. In this case, the detection may be performed by the above-described detection means, and air may be blown out to remove the attached dust. Moreover, you may blow out air for every predetermined time progress.

  FIG. 19 is a longitudinal sectional view showing a configuration example of a dust removing device for removing dust adhering to the inner wall of a pipe when a gas containing dust flows. As shown in the figure, the dust removing device has a scraping mechanism having a structure in which two rod-like scraping members 63 extending in the longitudinal direction of the main shaft 62 are disposed in a pipe 61 through which exhaust gas G3 containing dust flows. Yes. The main shaft 62 of the scraping mechanism is supported so that the scraping member 63 is in contact with the inner surface of the pipe 61 or is positioned with a minute gap, and a support seal mechanism 64 having a sealing action and the scraping mechanism are provided. A drive mechanism 65 that swings (rotates reciprocally at a constant angle) or rotates continuously or periodically around the main shaft 62 is provided.

  The main shaft 62 and the scraping member 63 are hollow pipes, and the hollows communicate with each other, and the cleaning gas G4 passes through the hollow of the main shaft 62 and the hollow of the scraping member 63 via a joint 66 such as a rotary joint. The scraping member 63 is jetted into the pipe 61 from the tip (upper end). A dust receiving portion 67 is provided at the lower end of the pipe 61, a water injection nozzle 69 for injecting water is provided on the inner wall surface of the dust receiving portion 67, and a drain pipe 70 is provided at the bottom of the dust receiving portion 67. ing.

  In the dust removing device having the above configuration, the gas G3 containing dust flowing into the pipe 61 is discharged through the exhaust pipe 68, but the dust adheres to the pipe 61. When the scraping mechanism is swung or rotated continuously or periodically around the main shaft 62 by the driving mechanism 65, dust adhering to the inner wall of the pipe 61 is scraped off by the scraping member 63 and is received by the dust receiving portion 67. Fall. At this time, the cleaning gas G4 such as air is jetted continuously or intermittently from the tip of the scraping member 63, so that dust in a range not reached by the scraping member 63 can also be removed.

  Since the dust removed by this method falls to the dust receiving portion 67 while being fine, if water is injected from this water injection nozzle 69 to this portion, the dust is discharged from the drain pipe 70 without clogging. When the exhaust gas G1 is a corrosive gas, if the ammonia gas is mixed with the cleaning gas G4, the inner surface of the pipe 61 can be neutralized and the progress of corrosion can be stopped.

  FIG. 20 is a diagram showing a configuration example when the dust removing device having the configuration shown in FIG. 19 is provided in the exhaust gas combustor of the exhaust gas processing device. As shown in the figure, a scraping mechanism having two rod-shaped scraping members 73 extending in the longitudinal direction of the main shaft 72 in the combustion chamber 30 into which the exhaust gas G1 from the semiconductor manufacturing facility flows, and the scraping mechanism A support seal mechanism 74 that supports the main shaft 72 so that the scraping member 73 contacts the inner surface of the combustion chamber 30 or moves in the inner circumferential direction with a small interval and has a sealing function, and the scraping mechanism is connected to the main shaft. A drive mechanism 75 that swings or rotates continuously or periodically around 72 is provided.

  Also, the cleaning gas G4 passes through the hollow of the main shaft 72 and the hollow of the scraping member 73 through the joint 76 such as a rotary joint, and is jetted from the upper end of the scraping member 73 into the pipe 71 constituting the combustion chamber 30. It is like that. A burner 81 is provided at the upper burner portion 10 on the inner wall surface of the combustion chamber 30, a cooling receiving portion 77 is provided at the lower end of the combustion chamber 30, and an exhaust port 78 is provided at a side portion of the cooling receiving portion 77. ing. A water injection nozzle 79 that injects water is provided on the inner wall surface of the cooling receiving portion 77. Further, a drain port 80 communicating with the inside of the cooling receiving portion 77 is provided at the lower end portion.

  Exhaust gas G1 from a semiconductor manufacturing facility or the like is heated by a flame formed by a burner 81, rendered harmless, and becomes high-temperature exhaust gas containing high-concentration dust. Since the temperature of the flame 82 formed by the burner 81 reaches about 2000 ° C., it is considered that most substances are melted when an object directly hits the flame 82. For this reason, since the inner wall surface temperature of the combustion chamber 30 immediately after the burner 81 is lower than 2000 ° C., dust adheres and is easily clogged. Moreover, the periphery of the burner part 81 is also the same.

  Under the above environment, when the scraping mechanism is rotated or rocked around the main shaft 72 by the drive mechanism 75, the dust attached to the inner wall surface of the combustion chamber 30 can be scraped directly by the scraping member 73. Blockage due to dust adhesion can be prevented. Further, even in a range where the scraping member 73 cannot be inserted due to the flame 82, the cleaning gas G4 is supplied through the joint 76 such as a rotary joint, and blown out from the upper end of the scraping member, thereby removing dust attached to the inner wall surface. it can.

  The exhaust gas G1 heated and combusted by the flame 82 flows into the cooling receiver 77, is cooled by the water jetted from the water jet nozzle 79, is discharged from the exhaust port 78, and the water containing the scraped dust is It is discharged from the drain port 80.

  FIG. 21 is a diagram showing another configuration example of the main shaft 72 and the scraping member 73 of the scraping mechanism. As shown in the figure, the scraping mechanism is provided with a large number of small holes 73 a communicating with the hollow portion on the outer peripheral surface of the scraping member 73. By supplying the cleaning gas G4 through the hollow of the main shaft 72 and the scraping member 73 via the joint 76 such as the rotary joint of FIG. 14, the cleaning gas G4 is blown to the inner wall of the combustion chamber 30 through the hole 73a. The air is also blown out from the upper end of the scraping member 73. As a result, the dust adhering to the gap d between the scraping member 73 and the inner wall surface of the combustion chamber 30 can also be removed by blowing away.

  FIG. 22 is a view showing another configuration example of a scraping mechanism including a main shaft 72 and a scraping member 73. As shown in the figure, the scraping mechanism is provided with a large number of small holes 73 a and 72 a communicating with the hollow portion on the entire surface of the scraping member 73 and the main shaft 72. By adopting such a configuration, by introducing the cleaning gas G4 into the hollow portion of the main shaft 72 and the scraping member 73, the dust is brought into the range of the gap between the scraping member 73 and the inner wall surface of the combustion chamber 30. Can be removed by blowing away. Also, dust attached to the main shaft 72 and the scraping member 73 itself can be blown away.

  In the embodiment shown in FIGS. 21 and 22, a large number of holes 72a and 73a communicating with the hollow portion are provided on the surfaces of the main shaft 72 and the scraping member 73, but the holes 72a and 73a are replaced with hollow holes. A slit communicating with the portion may be provided. Further, the configuration of the scraping mechanism shown in FIGS. 15 and 16 is naturally applicable to the scraping mechanism including the main shaft 62 and the scraping member 63 shown in FIG.

  Further, the number of scraping members 73 of the scraping mechanism is not limited to two, and three scraping members 13 may be provided on the main shaft 72 as shown in FIG. It may be more than this. Also in the case of FIG. 19, a scraping mechanism may be configured by providing three or more scraping members on the main shaft 62.

  By setting the number of the scraping members 73 to three or more, the number of times the dust is scraped per rotation of the scraping mechanism is increased, and it is possible to cope with a case where the dust concentration is high. Further, when the scraping mechanism performs a reciprocating rotational movement at a constant angle, dust in all regions can be scraped even if the swing angle is reduced. However, if the scraping member 73 is excessively increased, the combustion chamber 30 may be blocked due to dust adhering to the scraping mechanism itself.

  Although not shown, a scraping mechanism having the configuration shown in FIGS. 20 to 23 is installed in the exhaust gas treatment combustor shown in FIG. 1 so as to remove dust adhering to the burner portion 10 and the inner wall of the combustion chamber 30. You may comprise.

  In the dust removing apparatus having the configuration shown in FIGS. 19 to 23, the gas 61 and the gas G3 flowing into the pipe 61, the flame holding section 10, and the combustion chamber 30 are not only dust, but also the pipe 61, the flame holding section 10, and the combustion chamber 30. In the case where a component that may corrode by the action of corrosion or the like is included, a gas having a property of neutralizing the action is introduced into the cleaning gas G4 (for example, ammonia against the inflow of acid gas) In the range covered by the cleaning gas G4, the erosion action of the pipe can be suppressed.

  24 and 25 are diagrams showing another configuration example of the burner part of the exhaust gas treatment apparatus of the present invention, FIG. 24 is a longitudinal sectional view, and FIG. 25 is an L view of FIG. Compared with the burner unit 10 of FIGS. 3 and 4, for example, the burner unit 10 has a smaller height dimension H of the flame holding unit 18 and a smaller interval I between the air nozzle 15 and the auxiliary gas nozzle 16. Yes. That is, the air outlet of the air nozzle 15 is as close as possible to the auxiliary gas outlet of the auxiliary gas nozzle 16. Further, the distance J between the center line of the air nozzle 15 and the tangent line of the inner wall surface is made small so that the air blown out from the air nozzle 15 approaches the tangent line of the inner wall surface of the cylindrical body 11 as much as possible.

  In this way, by reducing the height dimension H of the flame holding portion 18 and reducing the interval I between the air nozzle 15 and the auxiliary combustion gas nozzle 16, the flow stays between the air outlet and the valley of the auxiliary combustion gas outlet. The dust that adheres to or adheres to the inner wall surface of the flame-holding portion 18 is blown off by the air flow and is prevented from adhering to the inner wall surface as much as possible.

  Further, since the air blown from the swirl nozzle 15 is close to the tangent line of the inner wall surface of the cylindrical body 11, the stay of the flow near the inner wall surface of the cylindrical body 11 is prevented and the dust is less likely to adhere to the inner wall surface.

  Moreover, the air nozzle 15 was provided so that the flow of the air blown out from the air nozzle 15 may be inclined downstream from the horizontal. When the inclination angle θ1 of the air nozzle 15 with respect to the horizontal plane is set to about 30 °, the dust adhesion preventing effect in the vicinity of the auxiliary combustion gas nozzle 16 is great. A large number of air nozzles 15 are provided so that the air outlets are uniformly opened in the circumferential direction of the inner wall surface of the cylindrical body 11, and a high-speed air flow immediately after blowing out with a high blowing effect spreads over the entire inner wall surface. I am doing so.

  The air introduction angle θ2 in the horizontal direction of the air nozzle 15 is θ2 = 360 ° / n. Here, n is an integer of 3 or more in the number of air nozzles 15 arranged in the circumferential direction. In particular, good results were obtained when the number n of air nozzles was 4, 8, 12, 16, 24.

  The ratio (H / K) of the inner diameter K to the height dimension H of the flame-holding portion 18 is conventionally 50 mm / 80 mm, but here it is 15 mm / 80 mm. In addition, the interval I between the lower air nozzle 15 and the upper auxiliary gas nozzle 16 is 16 mm, compared with 26 mm in the related art. Even if the inner diameter K increases or decreases, the interval I is constant. In addition, the distance J between the center line of the air nozzle 15 and the tangent line of the inner wall surface parallel to the center line is 5 mm, compared with 15 mm in the related art.

  FIG. 26 is a longitudinal sectional view showing another configuration example of the burner part of the exhaust gas treatment apparatus of the present invention. As shown in the figure, the burner portion 10 has an inner diameter of the opening 14a of the exhaust gas introduction pipe 14 gradually increasing downward, and further, the inner diameter of the cylindrical body 11 is gradually increasing downward. As a result, there is no angled portion such as a right angle inside the opening 14 a of the exhaust gas introduction pipe 14 and the inside of the cylindrical body 11. Further, an inverted frustoconical protrusion 11 a may be provided between the openings 14 a of the exhaust gas introduction pipe 14.

  Usually, the dust adhesion part in the burner part 10 adheres to a corner part or a part where air or exhaust gas stays. Here, as described above, the opening 14a of the exhaust gas introduction pipe 14 and the angled portion such as a right angle are eliminated inside the cylindrical body 11, and the exhaust gas staying part is eliminated between the exhaust gas introduction pipes 14. Dust is difficult to adhere to.

  As described above, according to the first to third aspects of the present invention, since the auxiliary combustion gas introduction portion for introducing the auxiliary combustion gas is provided in the auxiliary combustion gas nozzle of the burner portion, the cooling means for cooling the auxiliary combustion gas introduction portion is provided. Even if heated, the temperature rise is suppressed below the ignition point of the auxiliary combustion gas, so there is no risk of explosion of the auxiliary combustion gas.

  According to the second to third aspects of the present invention, since the flame does not directly contact the cooling jacket, the heat amount of the flame is not taken away by the cooling medium, and a large amount of heat can be used for the exhaust gas treatment.

  According to the invention described in claims 4 to 6, since the dust removing means for removing dust or preventing dust from adhering to the burner portion and / or the combustion chamber wall is provided, the burner portion and / or The exhaust gas treatment device can be operated for a long time without clogging the combustion chamber with dust.

  Further, according to the invention described in claim 7, the dust attached to the pipe is removed by swinging or rotating continuously or periodically by the scraping mechanism arranged in the pipe, The exhaust gas can flow with less pressure loss.

Further, according to the invention described in claims 8 to 9, the scraping member and the main shaft are made of a hollow pipe, and the main shaft and the scraping member are passed through the hollow of the scraping member from the outside of the pipe, so that the tip of the scraping member or many of the surfaces thereof By blowing out the cleaning gas from the holes or slits, it is possible not only to remove dust in the pipe that does not reach the scraping member, but also to remove dust adhering to the scraping mechanism itself. In addition, when high-temperature gas flows in the pipe, the durability of the apparatus itself is improved due to the cooling effect of the cleaning gas.

According to the invention described in claims 10 to 12, since the air nozzle is an air nozzle configured to blow a swirling air flow downward on the combustion flame formed downward of the opening, the nozzle portion It becomes an exhaust gas treatment device in which dust hardly adheres to the inner wall.

  According to the invention described in claim 13, since the exhaust gas inlet and the inner diameter of the cylindrical body are gradually increased toward the combustion chamber, there is no corner at right angles in the burner portion, and the nozzle portion It becomes an exhaust gas treatment device in which dust hardly adheres to the inner wall.

  In addition, according to the fourteenth aspect of the present invention, it is possible to provide an exhaust gas treatment apparatus that is compact and capable of efficiently treating exhaust gas containing harmful flammable gas and hardly decomposable gas.

It is a figure which shows the structure of the exhaust gas combustor of the exhaust gas processing apparatus which concerns on this invention. It is II sectional drawing of FIG. It is a figure which shows the structural example of the burner part of the waste gas processing apparatus which concerns on this invention. It is arrow A figure of FIG. It is a figure which shows the structural example of the burner part of the waste gas processing apparatus which concerns on this invention. It is arrow D figure of FIG. It is a figure which shows the structural example of the burner part of the waste gas processing apparatus which concerns on this invention. FIG. 8 is an arrow E view of FIG. 7. It is a figure which shows the structural example of the burner part of the waste gas processing apparatus which concerns on this invention. FIG. 10 is an arrow F view of FIG. 9. It is a figure which shows the structural example of the burner part of the waste gas processing apparatus which concerns on this invention. It is an external view of the cooling jacket of FIG. It is a figure which shows the structural example of the dust removal apparatus of the waste gas processing apparatus which concerns on this invention. It is a top view of the scraping board of FIG. It is a surface which shows the structural example of the dust removal apparatus of the waste gas processing apparatus which concerns on this invention. It is II-II cross-sectional arrow view of FIG. It is a surface which shows the structural example of the dust removal apparatus of the waste gas processing apparatus which concerns on this invention. It is the III-III cross section arrow directional view of FIG. It is a figure which shows the structural example of the dust removal apparatus in the piping which concerns on this invention. It is a figure which shows the structural example of the dust removal apparatus in the waste gas processing apparatus which concerns on this invention. It is a figure which shows the structural example of the dust removal apparatus in the piping which concerns on this invention. It is a figure which shows the structural example of the dust removal apparatus in the piping which concerns on this invention. It is a figure which shows the structural example of the dust removal apparatus in the piping which concerns on this invention. It is a figure which shows the structural example of the burner part of the waste gas processing apparatus which concerns on this invention. It is arrow L figure of FIG. It is a figure which shows the structural example of the burner part of the waste gas processing apparatus which concerns on this invention. It is a figure which shows the structural example of the conventional waste gas processing apparatus. It is the IV-IV cross section arrow directional view of FIG.

Claims (2)

A burner section; and a combustion chamber provided downstream of the burner section, forming a combustion flame from the burner section toward the combustion chamber, introducing exhaust gas into the combustion flame, and oxidizing and decomposing the exhaust gas In exhaust gas treatment equipment,
The burner portion has a cylindrical body whose top portion is closed and whose lower portion is opened. An exhaust gas inlet is provided at the top portion of the cylindrical body, an air nozzle is provided at a predetermined position on the side wall, and a side wall near the opening is provided with auxiliary combustion. A gas nozzle is provided to mix the exhaust gas introduced from the exhaust gas inlet and the air blown from the air nozzle, ignite the auxiliary combustion gas blown from the auxiliary combustion nozzle, and form a combustion flame below the opening Configured to
Providing a cooling means for cooling the auxiliary combustion gas introduction part for introducing the fuel gas into the auxiliary combustion gas nozzle ;
The auxiliary combustion gas introduction portion is an auxiliary combustion gas chamber or auxiliary gas introduction pipe provided on the outer peripheral side of the cylindrical body, and the auxiliary combustion gas nozzle is arranged at the tip of the auxiliary combustion gas chamber or auxiliary combustion gas introduction pipe. The cooling means is configured to supply a cooling medium to a cooling jacket provided adjacent to the auxiliary combustion gas chamber or the auxiliary combustion gas introduction pipe to cool the auxiliary combustion gas chamber or the auxiliary combustion gas introduction pipe. exhaust gas treatment apparatus characterized by the. The exhaust gas treatment apparatus according to claim 1 ,
The exhaust gas treatment apparatus, wherein the cooling medium is water, air, other liquid, or gas.

Images