KR900005988B1 - Limiting the presence of the oxides of nitrogen in regenerative heating system - Google Patents

Abstract

A method for limiting the presence of oxides of nitrogen in the exhaust gas leaving a regenerator during firing comprises injecting water or water vapour into the regenerator during firing and causing the water or water vapour to reach the combustion chamber of the regenerator by way of its heat storage bed which has been preheated during a previous heat collecting phase. The temp. of the combustion air is sensed after the combustion air leaves the bed but before the combustion air enters the combustion chamber. The water or water vapour is injected into the generator when the sensed temp. of the combustion air is above a preset level.

Description

A method for reducing the amount of nitrogen oxides in a heat regenerator and its exhaust gas

1 is a cross-sectional view of a heat regenerator of a heating apparatus capable of regenerating heat to remove a hole-prone substance from a heat storage bed of a heat regenerator and to reduce the amount of nitrogen oxides (NO _X ).

FIG. 2 is a schematic diagram of a suitable control system of a heating apparatus capable of thermal regeneration comprising two thermal regenerators of the type shown in FIG.

* Explanation of symbols for main parts of the drawings

1,1A, 1B: Regenerator 2: Shaft

3: main part 4: side part

5: main bore 6: side bore

7,9: cylindrical portion 8: conical portion

10: horizontal portion 11, 11A, 11B: heat storage bed

12 ball 13 flange

14: top surface 15,15A, 15B: hood

16: cylindrical wall 17: pipe

18: nozzles 19, 19A, 19B: inlet

20,20A, 20B: Regulator Valve

21,21A, 21B, 24,24A, 24B: Solenoid Valve

22: insert 23, 23A, 23B: discharge pipe

25,25A, 25B: Burner 26: Combustion Chamber

26: bore side 28, 28A, 28B: temperature sensor

40: firing sequencer 41A, 42B: reversing valve

43: combustion air supply section 44: exhaust extractor

46A, 46B: switch 48A, 48B: combustion position contact

49A, 49B: Cleaning position contact part 50A, 50B: Water supply part

51,51A, 51B: OR gate 52,52A, 52B: AND gate

56A, 56B: discharge duct

The present invention relates to a method for reducing nitrogen oxides in an exhaust gas emitted by a heat regenerating heating apparatus, and furthermore, to accomplish the above object and to remove a substance which is likely to be clogged in a hole of the heat storage bed from the heat storage bed. The present invention relates to a heat regenerator (regqenrator) of a heating apparatus capable of regeneration.

Heat regenerators include two or more thermal regenerators connected to a furnace that includes a charge that is heated by the combustion material supplied through the walls of the furnace.

The apparatus supplies waste heat in the form of waste gas in which the combustion material supplied by one heat regenerator leaves the furnace during the so-called firing phase, and the waste heat is in a heat collection, ie, another heat regenerator operating in the heat recovery stage. It is designed to be recovered.

Each heat regenerator includes a shaft to receive a heat storage bed disposed between the two openings.

One opening is intended to be in direct communication with the furnace to act as an outlet for discharging the combustion material into the furnace during the combustion phase of the regenerator and as an inlet to receive waste heat from the furnace during the heat recovery phase of the regenerator.

The other opening acts as an inlet for receiving combustion air to burn fuel in the combustion chamber during the combustion phase of the heat regenerator and as an outlet for exhausting the waste gas to the atmosphere as an exhaust gas during the heat recovery phase of the heat regenerator.

The heat storage bed recovers heat before exiting the exhaust gas unit during the heat recovery step.

The heat storage bed then releases the stored heat to heat the combustion air as it passes through the heat storage bed before the combustion air reaches the combustion chamber during the combustion phase.

The heat storage bed itself is of course permeable to fluids such as waste gas and air and has a porous structure of discrete particles of refractory material that stores heat.

The combustion chamber between the heat storage bed and the opening intended to be in direct communication with the furnace supplies the combustion air preheated to the combustion of the fuel during the combustion phase, whereby combustion material is obtained.

Fuel is injected into the combustion chamber during the combustion phase and a device is installed to ignite the fuel so that combustion occurs.

The combustion chamber may form part of a burner installed in a heat regenerator which forms part of a heating apparatus capable of thermal regeneration.

Typical examples of such heat regenerators are described in detail in U. S. Patent No. 4522588 and Pending U. S. Patent Application No. 8527894, based on published British Patent Application No. 2128742 A.

Preheating combustion air in the manner described above is a well-established technique for recovering heat from the padgas to improve the efficiency of the hot furnace.

One effect of preheating the combustion air is to raise the temperature of the flames resulting from the fuel combustion process.

This affects the combustion reaction and tends to increase the formation of nitrogen oxides, which are mainly composed of NO and NO ₂ .

In fact, if the fuel is a natural gas, the formation of dioxide increases markedly with the increase in the flame temperature and is mainly due to the heat-sorption of nitrogen under atmospheric pressure in the combustion air.

The amount of oxide produced is also determined by the time (retention time) the flame is held at the temperature at which it is at its peak.

Generation of nitrogen oxides (briefly known as NO _X) is as a result of combustion of a fuel with air and an air pollution of NO _X is causing acidification of the ratio in the exhaust gases leaving the heating apparatus heat renewable, in the atmosphere Hydrocarbons and NO _X interact to form phochemical oxidants and high NO ₂ emissions can cause clock degradation, which is undesirable for the environment.

If the Japanese, as some countries in already this legislation, and Europe, and similar legislation is expected, and ten more effective heat recovery device is widely adopted in playback mode it will be established in North America in order to limit the NO _X content in the emitted exhaust gases NO _X emissions It becomes essential to limit

A known method of reducing the NO _x level produced by the burners is to supply water vapor at the point of combustion.

The moisture may be supplied in the form of water in the form of liquid injected into the flame or in the form of steam in the form of steam injected into the flame.

When moisture is a liquid, it comes into contact with the flame to form steam.

The actual presence of water vapor in the combustion chamber increases the volume and thermal mass of the gas in the combustion zone.

This is a result of reducing the amount of NO _X in the combustion gas.

However, injecting water or water vapor at the point of combustion will result in the removal of heat from the flame and no recovery of heat from the waste gas.

The overall efficiency of the process is therefore reduced.

It is an object of the present invention to provide a technique for limiting the amount of nitrogen oxides in the exhaust gas leaving the heat regenerator of a heating apparatus capable of thermal regeneration while reducing the overall process efficiency obtained by the above described method.

It is a further object of the present invention to provide a thermal regenerator which is adapted to join the above and consequently removes from the heat storage bed of the heat regenerator a substance which is susceptible to the hole blocking the hole of the heat storage bed.

In accordance with one aspect of the present invention, the Applicant provides a method of limiting the amount of nitrogen oxides in the exhaust gas leaving the heat regenerator, which injects water or steam through the injection nozzle into the heat regenerator during the combustion step, The heat storage bed preheated during the heat recovery step is configured to reach the combustion chamber of the heat regenerator.

According to another feature of the invention, the present inventors provide a thermal regenerator adapted to limit the amount of nitrogen oxides in the exhaust gas leaving the thermal regenerator, wherein the thermal regenerator includes a shaft containing a heat storage bed and water or water during the combustion step. An apparatus for injecting water vapor into the heat regenerator through the injection nozzle is installed in such a way that water or steam can enter the combustion chamber of the heat exchanger via a heat storage bed that is preheated during the previous heat recovery step.

The normal temperature at which the heat storage bed of the heat regenerator is preheated, for example, at 1200 ° C. (if water is injected rather than water vapor), the water evaporates through the heat storage bed and the product vapor is also preheated before entering the combustion chamber.

If steam such as steam is injected instead of water, the steam will simply preheat and enter the combustion chamber through the heat storage bed.

Either way, due to the presence of water vapor in the combustion chamber of the thermal regenerator during the combustion process, the volume and thermal mass of the combustion gas increases, which limits the level of NO _{x in} the gas.

However, because steam is already preheated by the heat storage bed and much of the heat is recovered when the steam leaves the device by the heat storage bed of another heat regenerator, a small amount of additional heat is required to raise the temperature of the water vapor to the process temperature. Rarely needed.

Therefore, the overall efficiency of the process is not greatly reduced.

It has been found that when water or water vapor passes through the heat storage bed, it has the effect of minimizing reducing the overall process efficiency while the heat storage bed is cooled.

If steam is to be generated in a particular plant, it is preferable to inject water rather than steam because it is much more efficient to produce steam in the heat regenerator with heat released from the heat storage bed than to separate steam from the boiler.

However, if steam can only be obtained, for example, if steam is obtained as a by-product in the next process, it is preferable to inject steam rather than water to evaporate the water to save the heat released from the heat storage bed. .

Water or steam is injected into the combustion air at the upper point of the heat storage bed with respect to the direction of travel of the combustion air and the heat storage bed is preferably arranged such that the surface furthest from the combustion chamber is at the top.

In a preferred specific embodiment of the invention, water or steam is produced if the preheated combustion air is detected by the temperature sensor and the temperature of the combustion air is below a predetermined level before the preheated air reaches the combustion chamber of the heat regenerator during the combustion phase of the heat regenerator. Stop injecting into the heat regenerator.

The value of the reference temperature is determined according to the amount of NO _X in the exhaust gas.

As can also be seen from the user's point of view, it is generally desirable to operate at the highest possible flame temperature to increase the heating efficiency of the process.

By monitoring the temperature of the preheated combustion air, it is possible to keep the flame temperature at all to the level not lower than required to satisfy the law of the NO _X level emitted.

According to another feature of the invention, the inventors generally inject water or water vapor into the shaft to receive the heat storage bed facing upwards, the surface of the heat storage bed at the top when the shaft is in a generally upward facing position. To provide a regenerator, an inlet for supplying water or water vapor to the injector, and an outlet for discharging water or water vapor that permeates the heat storage bed from the heat regenerator, the outlet having a shaft generally upwards. It is placed under the surface of the bottom heat storage bed.

In addition to reduce the amount of NO _X in the exhaust gas heat exchanger it is adapted to remove the "easy matter to clog in the hole" block the holes of the heat storage bed from the heat storage bed of the heat regenerator.

"Substances that are likely to be clogged" means a substance that can be dissolved in water or a substance that can be transported along the water if it is insoluble in water, for example a small or light substance.

Such material is carried by the waste gas of the furnace and accumulates in a hole in the heat storage bed of the regenerator.

Such materials may be flux and may be materials such as powder or metal or glass powder from the material being heated.

When the heat regenerator is not working, water or steam sprayed on the top surface of the heat storage bed penetrates into the heat storage bed, dissolving any substance that can be dissolved in water or washing away light substances. Water is discharged through the outlet.

This eliminates the need to remove the bed to clean the heat storage bed and makes the heat storage bed more useful.

Preferably the inlet has a valve for controlling the supply of water or water vapor from the inlet to the injector, and if the temperature of the combustion air detected after preheating is higher than the predetermined moisture, the valve during the combustion phase of the heat regenerator. A device is installed to control the valve so that it opens.

Suitably, the device for regulating the valve at the water or steam inlet is adapted to open the valve when the heat regenerator is neither in the combustion nor the heat recovery stage.

Conveniently, the outlet has a valve that regulates the discharge of water or water vapor from the outlet and the valve is closed during the combustion or heat recovery phase and the valve can be opened when the heat regenerator is neither a combustion nor a heat recovery phase. The device that controls the is installed.

Specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In FIG. 1 the heat regenerator 1 comprises a shaft 2 composed of a refractory material and having a main portion 3 and a side portion 4 and a main portion 3. Generally has a vertically facing main bore 5 and side 4 defining a side bore 6.

The main bore 5 has an upper cylindrical portion 7 with a truncated cone portion 8 tapering downwards.

The side bore 6 has an upwardly angled cylindrical part 9 from the lowest part of the cylindrical part 7 and a generally horizontal part 10 from the cylindrical part 9.

The upwardly angled cylindrical portion 9 of the main bore 5 and the side bore 6 functions as a device for recovering heat from the waste heat during the heat recovery step of the heat regenerator 1 and the heat regenerator 1 During the combustion phase of the heat storage bed 11 which functions as a device for preheating combustion air is received.

The heat storage bed 11 may be composed of a plurality of refractory particles, in which case the ball 12 of known type almost fills the main bore 5 and partially fills the cylindrical portion 9.

The hood 15 is secured with a flange 13 to the shaft 2 at the point on the top surface 14 of the heat storage bed, through which the combustion air is fed during the combustion phase. ) Is preheated by the heat storage bed (11), enters in the opposite direction during the heat recovery step, gives waste heat to the heat storage bed (11) and leaves the jumbo (5).

The hood 15 has a cylindrical wall 16 next to the flange 13 and a pipe 17 extends horizontally across the top surface 14 through the wall 16.

The pipe 17 is equipped with several spray nozzles facing the top surface 14 of the heat storage bed 11.

This nozzle 18 sprays water on the top surface 14 of the heat storage bed 11 when water is supplied from the inlet 19 to the pipe 17.

It will be appreciated that if waste steam can be obtained, steam can be supplied from the nozzle 18 instead.

The inlet 19 has a regulator valve 20 for adjusting the amount of water flow into the pipe 17 and an open-closed solenoid valve 21 for adjusting the amount of water flow into the pipe according to the method described subsequently. ) Is installed.

The base of the shaft 2 has a hole in the center and a fire resistant insert 22 is located in the hole.

The insert 22 also has a hole in the center to receive the downwardly extending discharge pipe 23 for receiving water penetrating through the heat storage bed 11.

The discharge pipe 23 is equipped with a solenoid valve 24 of the open-closed form which is then adjusted according to the method described.

A fireproof burner 25 in the form of a pore is fixed to the side portion 4 of the shaft 2 and defines a cylindrical combustion chamber 26 communicating with the side bore 6 via the side bore 27. .

Although not shown, the burner 25 has a fuel inlet like a conventional burner for injecting fuel into the combustion chamber 26 for combustion with combustion air leaving the heat storage bed 11 and entering the side bore 6. have.

Although not shown, the burner has an ignition device such as a pilot burner for igniting fuel entering the combustion chamber 26.

Burner 25 is fixed to the wall of the furnace (not shown) to supply combustion material for heating the material to be heated in the furnace during the combustion step.

During the heat recovery step, the burner serves as an inlet for receiving waste heat in order to supply waste heat for the heat regenerator 1 to store in the heat storage bed 11 from the furnace.

The temperature sensor 28 extends through the wall of the side section 4 through the horizontal section 10 and is provided with the preheated combustion air during the heat recovery step before the preheated air enters the combustion chamber 26 for the purposes described above. Sense the temperature.

In FIG. 2, elements similar to those shown in FIG. 1 are denoted by the same numbers, the only difference being that the elements which form part of a heat regenerator or which control the heat regenerator have a suffix "A" after each number For other thermal regenerators they have a suffix "B" after each number.

The heat regenerator shown is operated in the usual way and the operation of the two heat regenerators 1A and 1B is such that the heat regenerator 1B recovers heat when the heat regenerator 1A is combusted and the heat regenerator 1B When burned, the heat regenerator 1A is controlled by a known type of combustion sequencer such as recovering heat.

During operation, the regenerator alternates between the combustion and heat recovery stages and the conversion from one stage to another is controlled by time or temperature as usual.

Each heat regenerator has reversal valves 41A and 41B, which are also of known type, and each reversal valve uses the hoods 15A and 15B of the heat regenerators 1A and 1B to burn combustion air during the combustion phase. It may be operated with a signal from the combustion sequencer on the appropriate lines 42A, 42B to connect to the supply 43 or to the exhaust extractor 44 connected to the exhaust duct during the heat recovery step.

As can be seen when the reversing valve 41A connects the hood 15A to the combustion air supply 43, the reversing valve 41B connects the hood 15B to the exhaust extractor 44 and the reversing valve 41A. Is connected to the exhaust extractor 44, the reversing valve 41B supplies the hood 15B to the combustion air supply 43. As shown in FIG.

Although not shown, the combustion sequencer 40 also uses the burner 25A of each thermal regenerator in a well known manner such that fuel is injected into the burner 25 only when either thermal regenerator 1 burns with the preheated combustion air. Control injection of fuel into 25B).

The combustion sequencer 40 is operated by two switches 46A and 46B and each thermal regenerator 1A and 1B is equipped with a switch 46.

Each switch member 47A, 47B is configured to activate the sequencer 40 so that the heating device capable of thermal regeneration is activated so that the combustion sequencer 40 is powered by the power line. ) Must be moved to each "burn" position contact 48A, 48B.

In order to shut down the device, each switch member 47A, 47B must be moved to bite into each " clean " position contact 49A, 49B. In this position, the heat storage beds 11A and 11B of each of the heat regenerators 1 can be cleaned by removing substances which are likely to be caught in the holes with water.

Each water inlet 19A, 19B controls solenoid valves 21A, 21B and regulator valves 20A, 20B of each water inlet to provide water from each of the water supply units 50A, 50B. Is supplied.

The solenoid valves 21A and 21B are OR gates so that the solenoid valves 21A and 21B are closed unless the solenoid valves 21A and 21B are operated to be opened by the respective OR gates 51A and 51B. Controlled by 51A and 51B.

OR gates 51A and 51B are actuated when each switch member 47A and 47B is bitten by wash position contacts 49A and 49B or when the appropriate AND gates 52A and 52B are actuated.

A signal from the combustion sequencer 40 to burn the heat regenerators 1A and 1B through each of the lines 53A and 53B is transmitted and the combustion air temperature in the heat regenerators is monitored by the temperature sensors 28A and 28B. Each AND gate is activated when detected and above a preset temperature.

In the latter case, the operating signal is sent to the AND gates 52A and 52B when the sensed temperature is higher than the preset level by comparing the sensed temperature with the preset temperature in the comparators 54A and 54B.

Each of the switch members 47A such that the switch members 47A and 47B can be opened to discharge water through the discharge pipes 23A and 23B by the discharge ducts 56A and 56B to the outlets 55A and 55B. The solenoid valve 24A, 24B for draining water is always closed unless) 47B is bitten by its washing position contacts 49A, 49B.

When a thermally regenerated heating device is operated to supply heat to the furnace load, each switch member 47A, 47B snaps into each combustion position contact 48A, 48B and the combustion sequencer 40 is activated. .

In this case, the combustion sequencer 40 burns one of the heat regenerators and recovers the other heat.

In this way the combustion air is preheated by the previously heated heat storage bed 11 in the burning regenerator.

If detected by the temperature sensor 28 and the temperature of the combustion air is higher than the preset upper limit, the AND gate 52 is operated to operate the OR gate to open the solenoid valve 21 of the water injection section.

In this way water is supplied to the pipe 17 and sprayed by the nozzle 18 to the top surface 14 of the heat storage bed 11.

This water is converted to steam at a temperature level of the heat storage bed 11 where the temperature is high enough.

Under normal conditions, the temperature other than this part of the heat storage bed 11 is 200 ° C. or higher, so the water evaporates immediately.

This vapor is entrained through the flow of combustion air as it passes through the heat storage bed 11 to preheat the combustion air.

By being a fuel and preheated air in the combustion chamber 26 of the burner 25 to the combustion vapors of the combustion air thereby reducing the level of NO _X.

The combustion product enters the furnace and heats the load contained therein.

The resulting waste gas enters another heat regenerator and preheats the cooled heat storage bed for the next combustion step.

This process continues until the temperature of the preheated combustion air in the heat regenerator of the combustion stage drops to a predetermined temperature level, in which case the AND gate 52 will be activated and the solenoid valve 21 will close to close the water spray. It is over.

In either case, even if water is supplied to the heat regenerator of the combustion stage, the AND gate will operate at the end of the combustion stage to switch to the heat recovery stage.

This process will continue during that period when the system is operating.

When the system is shut down for cleaning purposes, the switch member 47 will engage each wash position contact 49.

Therefore, in this case, each OR gate 51 is operated to open the solenoid valve 21 for water injection so that water can be sprayed onto the heat storage bed 11 for cleaning.

In addition, the solenoid valve 24 for discharging water is opened to discharge water from the heat regenerator 1.

The foreign matter that penetrates into the heat storage bed 11 is discharged from the furnace load and includes a light substance that can be dissolved in the water blocking the hole of the heat storage bed 11, so that the heat storage bed 11 is discharged. Can be cleaned.

Claims (13)

Leaving the heat regenerator characterized in that the water or steam is injected into the heat regenerator through the injection nozzle during the combustion step, and the water or steam is sent to the combustion chamber of the heat regenerator via the preheated heat storage bed during the previous heat recovery step. A method for reducing the amount of nitrogen oxides in the exhaust gas. 2. A method according to claim 1, characterized in that water or steam is injected into the combustion air at an upstream point of the heat storage bed in the direction of movement of the combustion air. 3. A method according to claim 2, wherein the heat storage bed is arranged such that the surface of the heat storage bed furthest from the combustion chamber is at the top. The method of any one of the preceding claims, wherein the combustion air is sensed before entering the combustion chamber and after exiting the heat storage bed and the injection of water or steam into the heat exchanger if the temperature of the combustion air is below a predetermined temperature level. Stopping. In a heat regenerator configured to limit the amount of nitrogen oxides in the exhaust gas leaving the heat regenerator, water or water vapor is transferred to the heat regenerator via a shaft containing the heat storage bed, a heat storage bed preheated during the previous heat recovery step. And a device for injecting water or water vapor into the heat regenerator through the injection nozzle during the combustion step to enter the combustion chamber. 6. The heat regenerator of claim 5, wherein the device for injecting water or water vapor into the heat regenerator is arranged to inject water or water vapor into the combustion air at an upstream point of the heat storage bed in the direction of combustion air movement. . 7. The heat regenerator of claim 6, wherein the heat storage bed is disposed so that the surface of the heat storage bed furthest from the combustion chamber is at the top. 8. A device according to any one of claims 5 to 7, wherein an apparatus is provided for sensing the temperature of the combustion air before the combustion air enters the combustion chamber, and if the temperature of the combustion air is lower than the preset temperature level, the injection of water or water vapor And a device responsive to the temperature sensing device to be stopped. A shaft for receiving a heat storage bed generally facing upwards, a device for injecting water or water vapor onto the surface of the top heat storage bed when the shaft is in a generally upward position, supplying water or steam to the injection device And an outlet for discharging water from the heat regenerator through the heat storage bed, under the surface of the bottom heat storage bed when the shaft is generally in an upward position. Heat regenerator. 10. The method of claim 9, wherein if the temperature of the combustion air sensed after preheating having a device for regulating the supply of water or water vapor from the injector to the injector is above a predetermined temperature level, And a device for controlling the valve so that the valve opens. 11. The heat regenerator of claim 10, wherein the inlet valve is opened by the inlet valve regulating device when the heat regenerator is neither a combustion nor a heat recovery step. 12. The valve according to any one of claims 9 to 11, wherein the inlet has a valve for controlling the release of water or water vapor from the outlet, wherein the valve is closed during the combustion phase or the heat recovery phase and the thermal regenerator is neither the combustion phase nor the heat. Or a device for controlling the valve so that the valve opens. A heating apparatus capable of heat regeneration according to any one of claims 5 to 12, comprising two or more heat regenerators.

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