KR20160098578A - Conveniently as possible soot blower soot and scale removal device - Google Patents

Abstract

According to the present invention, a soot blower device capable of easily removing soot and scale comprises: a steam supplying unit disposed outside a combustion structure to supply steam to the inside of the combustion structure; a steam path opening and closing unit installed in a path of the steam supplying unit and having an electronic valve controlling a supply of steam; a rotation sleeve tube having one side connected to the steam supplying unit to be able to rotate and the other side connected to the inside of the combustion structure; a plurality of spray nozzles mounted on an outer surface of the rotation sleeve tube at regular intervals to spray steam in a screw form; a wall box provided between the steam supplying unit and the combustion structure to rotatably support the rotation sleeve tube and having an air introduction tube introducing external air of the combustion structure formed on one side thereof to introduce the external air into the inside of the combustion structure; an optical material catalytic member mounted in a tube connected with the steam path opening and closing unit and connected to the high pressure and temperature steam to discharge negative ions; and an ozone generation device connected to the air introduction tube to supply the small amount of ozone. Therefore, the soot blower device can supply steam along with negative ions naturally discharged from an optical catalyst material when the steam is supplied to the inside of a combustion chamber, and can easily remove soot laminated on a surface of a combustion structure by supplying external air supplied to the inside of the combustion structure along with ozone components. Also, the soot blower device can more easily remove a scale layer by changing the scale layer in an acicular structure including sulfur oxides into in a globular structure, and can prevent the soot and the scale layer from being attached again.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soot blowing apparatus and a soot blowing apparatus,

The present invention relates to a soot blower, and more particularly, to a soot blower having a structure in which an anion is supplied together with steam injected into the interior of a combustion structure, external air supplied into the combustion structure and a small amount of ozone are supplied together, The present invention relates to a soot blower apparatus capable of preventing scale removal and reattaching of a needle-like structure including a stacked soot and sulfur oxides, and a soot blower apparatus capable of easily removing scale.

As concerns about the environment including the air pollution problem have been raised in general, it has begun to strengthen regulations related to the combustion gas emission of the power plant centered on developed countries.

Since the domestic thermal power plant started regulating the emission of nitric acid gas (NOx) sulfuric acid gas (SOx) since 2001, the existing domestic thermal power plant has been using SOOT BLOWER to remove SOOT related to denitrification and desulfurization equipment. Installation is on the rise.

Among them, the soot blowers related to the desulfurization equipment are as follows. So far, the soot blower types imported from foreign countries have been replaced by the part retractable type that LANCE TUBE is located inside GGH (GAS-GAS HEATER) Respectively.

However, in the soot blower of the part retractable type contained in the GGH, since the lance tube was directly exposed to the sulfuric acid gas, it had to suffer frequent damage and corrosion of the lance tube as well as the spray nozzle attached to the lance tube.

On the other hand, when the boiler or incinerator of a large thermal power plant is operated for a long time, the suits are attached to the boiler wall or the tube.

Therefore, if the attached soot is not periodically removed, the attachment of a large amount of soot is accelerated, thereby obstructing the flow of the gas by the attached soot, as well as raising the internal pressure of the boiler due to the gas accumulated in the boiler .

As a result, it interferes with the increase in the thermal efficiency of the boiler, and the interruption of the gas flow leads to an increase in the internal pressure. Therefore, if the soot is not removed periodically, the power generation facility may be shut down in the future.

A device that plays this important role is the sootblower and is installed to remove the attached soot.

FIG. 10 shows an inner appearance of the boiler after a general soot blower operation, wherein a lot of suckers are removed from the heat exchanger tube.

As described above, the conventional soot blower includes a long retractable soot blower, a partially retractable soot blower, a rotary soot blower, a wall blower, .

The long retractable soot blower is a type that is used for boiler, high temperature super heater (super heater) and economizer (usually 400 ° C or more). When not using the machine, Remove the LANCE TUBE to protect it. Therefore, it is designed to protect lance tube and nozzle at high temperature. It is a machine that rotates during operation of sootblower and ejects steam and compressed air while advancing and retracting by a predetermined distance.

In addition, the partially retractable soot bluer is a type for efficiently cleaning the interior of the boiler's economizer, the air preheating heater, and the SCR, in which the lance tube of a certain length is located inside the boiler. It is installed in a relatively low temperature zone (below 400 ° C).

Further, there is an advantage that there is no restriction on the installation even if the space is small outside the boiler. When the cycle box is moved by a preset distance, an operating mechanism is activated to open a poppet valve. Steam enters the lance tube through the steam inlet tube and is injected through the nozzle at the end of the tube Blowing is started to remove the suet on the surface of the boiler tube.

The rotary sootblower can be blown only at the fixed position by the rotation operation of the element tube, and the steam introduced through the poppet valve is directly injected into the return tube through the nozzle of the element tube . The element tube is also located inside the boiler and is installed at low temperature (below 400 ° C).

Wall blowers are installed on boiler walls to remove soot attached to a number of water tubes installed in boiler walls. When the lance tube is inserted, the angle of the nozzle is directed toward the wall of the boiler so that steam can be sprayed. It is a machine that only professionally removes suits of boiler wall.

However, in the inner wall of the combustion chamber of a boiler or the like, the water contained in the combustion chamber and the sulfur dioxide contained in the combustion gas in the combustion process together with the soot in the combustion process are reacted (H _{2 O + SO 2 = H 2} SO 3) , etc. as the sulfur oxide (H ₂ SO ₃₎ and Knox (NOX) is deposited on the furnace walls and are attached with heat exchanger tube metal surfaces.

Such attachments and the like are corrosive to the inner wall of the combustion chamber made of a metal material and the heat exchange pipe, and it is necessary to remove them together when the soot is removed.

That is, the conventional sootblower is a method of removing the soot blower depending on the high-pressure superheated steam and the air, so that the soot stacked on the surface of the combustion chamber wall, the heat exchanger tube, and the like (hereinafter referred to as the combustion structure) can be easily removed.

However, sulfur oxides (H ₂ SO ₃ ) and oxides (NO x) adhered to the metal surface of the combustion structure are deposited on the metal surface for a long period of time while forming a needle-like structure, and thus are not completely removed by high- There was a limit.

Therefore, the scale layer forming the needle-shaped structure which can not be completely removed is stacked for a long period of time to form a scale layer having a considerable thickness as shown in FIG. 9A, and the soot generated in the combustion again is stacked repeatedly, And became a main factor for lowering combustion and heat exchange efficiency.

That is, the soot accumulated outside the scale layer can be removed by the soot blower, but the scale layer can not be easily removed, so that the corrosion of the metal surface is progressed by the scale layer, so that the combustion chamber wall or heat exchanger tube is cracked or damaged A serious problem occurs.

Accordingly, there was a troublesome and uneconomical problem of manually removing the accumulated scale layers accumulated over a long period of time by putting the workforce in a state where the operation of the thermal power plant or the incinerator was stopped for a few days.

In addition, as the soot removal process is repeated with high-pressure superheated steam and air, the scale layer remaining on the metal surface becomes a factor for accelerating the corrosion more rapidly, and in particular, the problem of shortening the replacement time of the thin- .

Meanwhile, the conventional wall blower connects the sleeve tube coupled to the poppet valve and the lance tube for introducing the steam to the inside of the boiler, by using a coupling or a socket, thereby preventing cracking and warping of the tube due to shrinkage and expansion in the boiler Respectively.

However, if the sleeve tube and the lance tube are coupled using a coupling or a socket, damage or wear of the lance tube may occur. If the sleeve tube needs to be replaced, it is difficult to separate the tube and the lance tube.

Also, there is a shortcoming in preventing the straightness of the sleeve tube and the lance tube from being deformed by the above-described coupling method.

In the area where the sleeve tube and the poppet valve are coupled, a square gland packing is provided. In this case, a leakage water tightness is required to be improved.

In addition, there is a serious problem of leakage of steam due to excessive wear due to corrosion and rotation due to moisture and foreign substances introduced into the sleeve tube at the area where the sleeve tube and the poppet valve are coupled.

The above-described technical structure is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

Korean Patent Registration No. 10-1367541 (Lee, Soon) 2014. 02. 19

(-) electrons naturally emitted from the photocatalyst material when supplying steam for removing the soot, and supplying a small amount of ozone component to the outside air supplied to the inside of the combustion structure, So that the scale layer of the needle structure containing sulfur oxides can be changed into a spherical structure to be easily removed, and it is possible to easily remove the soot and the scale which can prevent reattaching of the soot and scale layer And to provide a sootblower device.

Another object of the present invention is to provide a soot blower which is connected to a sleeve tube and can replace and maintain the lance tube disposed inside the boiler conveniently and can prevent leakage and deformation of the lance tube, ≪ / RTI > device.

It is another object of the present invention to provide a soot blower device in which a heat-resistant coating layer is formed on the outer surface of a vortex sleeve tube by thermal spray coating to improve the durability of the soot attachment prevention and corrosion.

The soot and the scale can be easily removed from the soot blower according to the present invention may include a steam supply unit disposed outside the combustion structure to supply steam into the combustion structure; An electronic steam flow path block provided in the steam supply line and having an electromagnetic valve for controlling steam supply; A rotary sleeve pipe rotatably connected to the steam supply part at one side and connected to the inside of the combustion structure at the other side; A plurality of spray nozzles mounted on the rotary sleeve tube at an interval on the entire outer surface thereof for spraying steam in the form of a screw; A wall box provided between the steam supply unit and the combustion structure for rotatably supporting the rotary sleeve tube and having an air inlet pipe for introducing outside air of the combustion structure into the combustion structure; A mineral catalyst member mounted in a pipe connected to the electronic steam flow path portion and contacting with the high temperature and high pressure steam to emit (-) electrons; And an ozone generator connected to the air inlet pipe to supply a small amount of ozone. The soot blower according to claim 1,

According to the present invention, the mineral catalyst member is a porous structure having tourmaline as a main component and can include a plurality of steam passing holes.

According to the present invention, it is preferable that the ozone concentration supplied from the ozone generator is 0.01 PPM to 1 PPM.

According to the present invention, the rotary sleeve pipe is divided into a first sleeve pipe rotatably connected to the steam supply unit, and a second sleeve pipe connected to the combustion structure and having the injection nozzle, The tube and the second sleeve tube may be detachably bolted together.

According to the present invention, a first flange is provided at one end of the first sleeve tube, and a second flange corresponding to the first flange and bolted to the first flange is provided at one end of the second sleeve tube And a coupling region of the first flange and the second flange may be provided inside the combustion structure.

According to the present invention, the injection nozzle comprises: a fixing part welded or screwed to a coupling hole formed in the outer circumferential surface of the rotary sleeve tube and having a fastening hole in the center; a plurality of through holes formed radially around the fastening hole; A nozzle body including a mounting portion provided on the upper portion of the through hole; And a nozzle head part which is formed with a coupling part which is adjustably screwed up and down in the center of the through hole and a curved part and an inclined part which extend outwardly from the coupling part to form a steam discharge port between the inclined part and the seating part; As shown in FIG.

According to the present invention, the injection nozzle comprises: a fixing part welded or screwed to a coupling hole formed in the outer circumferential surface of the rotary sleeve tube and having a fastening hole in the center; a plurality of through holes formed radially around the fastening hole; A nozzle body including a mounting portion provided on the upper portion of the through hole; A nozzle head part formed of a curved part and an inclined part extending outwardly from the coupling part to form a steam discharge port between the inclined part and the seating part; A resilient member that is assembled to the outside of the fastening portion so as to elastically downwardly move the nozzle head; And a fixing member fixed to the coupling portion to support the elastic member.

According to the present invention, the through-hole may be inclined in the spiral direction while the outlet from the inlet is inclined inward toward the fastening hole.

According to the present invention, the coupling hole may be welded or screwed, and the inner peripheral surface may further include a detachable member having a threaded portion to be screwed with the fixing portion of the nozzle body.

According to the present invention, it is possible to further include a packing portion provided in a coupling region of the rotary sleeve tube and the steam supply portion, and the packing portion may be formed by fitting a plurality of packing members each having fitting grooves into each other.

According to the present invention, the packing portion may include a pair of first packing members disposed at the outermost positions, respectively; And a plurality of second packing members provided between the pair of first packing members.

According to the present invention, the fitting groove is provided in an area where the pair of first packing members and the plurality of second packing members are in contact with each other, and the pair of first packing members and the plurality of second packing members are engaged with the fitting groove To each other.

According to the present invention, the pair of first packing members may be made of a metal material, and the plurality of second packing members may be made of a rubber material.

According to the present invention, the rotary sleeve tube and the steam supply unit may further include a bushing member which is provided together with the packing unit.

The present invention may further comprise a helical guide member provided in the wall box and spirally rotating the air introduced through the air inlet pipe to introduce the air into the combustion structure.

 According to the present invention, the outer surface of the rotating sleeve tube may include a heat-resistant coating layer, and the heat-resistant coating layer may be formed of a spray coating layer having a surface roughness of 3 to 8 RMS.

The soot blower apparatus according to the embodiment of the present invention, which is constructed as described above, facilitates the removal of soot and scale, has the following advantages.

When the steam is supplied into the combustion chamber, anions naturally spontaneously released from the photocatalyst material are supplied together. By supplying a small amount of ozone component to the outside air supplied into the combustion structure, it is possible to easily remove the stacks on the surface of the combustion structure .

In addition, since the scale layer including sulfur oxide is mainly loosened to the spherical structure, the scale layer can be more easily removed, and the effect of reattaching the soot and scale layer can be also provided .

In addition, since the sleeve pipe and the feeding pipe are detachably bolted to each other, the feeding pipe can be easily separated or combined, so that the rotating sleeve pipe can be easily serviced.

Also, by the above-described bolt connection method, it is possible to prevent leakage in the coupling region of the first sleeve tube and the second sleeve tube, and deformation of the rotating sleeve tube can be prevented.

Further, since the heat-resistant coating layer is formed on the outer surface of the rotary sleeve tube, the attachment of the soot is prevented, and the corrosion phenomenon is prevented, thereby providing an advantage that the replacement period of the rotary sleeve tube can be increased.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional perspective view showing a configuration of a soot and a soot blower apparatus which are easy to remove scale according to an embodiment of the present invention; FIG.
2 is an exploded perspective view of the sootblower of FIG.
Figure 3a is a cross-sectional view of Figure 1;
3B is a cross-sectional view showing a packing part.
FIG. 4 is a cross-sectional view showing a soot and a soot blower apparatus which can easily be descaled according to another embodiment of the present invention.
5 is a plan sectional view of a state in which a part of an upper end of a nozzle head is cut in order to explain a spraying structure of the spray nozzle of the present invention.
6 is a longitudinal sectional view showing another embodiment of the injection nozzle of the present invention.
7A to 7C are vertical cross-sectional views showing various arrangements of the spray nozzles of the present invention.
8 is a longitudinal sectional view showing another embodiment of the spray nozzle mounting structure of the present invention.
9A is an enlarged view for explaining a soot and a scale layer adhered to the combustion chamber wall or the surface of the heat exchange tube in an acicular structure.
FIG. 9B is an enlarged view of a scale layer in a state where soot is removed by steam according to the present invention. FIG.
Fig. 10 is an image showing a state in which the soot is removed from the boiler and the heat exchanger after the operation of the soot blower, and the scale layer remains.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings, which are intended to illustrate the present invention in a manner that allows a person skilled in the art to easily carry out the invention. And does not mean that the technical idea and scope of the invention are limited.

1 is an exploded perspective view of a soot and a soot blower apparatus in which descaling is easily performed according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the soot blower apparatus of FIG. 1, Fig. 4 is a cross-sectional view showing a soot according to another embodiment of the present invention, and a soot blowing apparatus which is easy to remove scale. Fig.

FIG. 6 is a longitudinal sectional view showing another embodiment of the injection nozzle of the present invention, and FIGS. 7A to 7C are cross-sectional views illustrating the spray nozzle of the present invention, FIG. 7C is a longitudinal sectional view showing various arrangements of the spray nozzles of the present invention, and FIG. 8 is a longitudinal sectional view showing another embodiment of the spray nozzle mounting structure of the present invention.

As shown in these drawings, the soot and the scale can be easily removed from the soot blower 1 according to the present embodiment. The soot blower 1 includes a steam supply unit 100, an electronic steam flow path switching unit 120, a rotary sleeve tube 200, 40, a wall box, a mineral catalyst member 50, and an ozone generator 30.

The steam supply unit 100 supplies steam supplied from the steam supply unit 10 into the combustion structure BS (see FIG. 7) and serves to open and close the steam flow channel.

In this embodiment, the steam supply unit 100 includes a valve body 110 and a valve body 110, as shown in FIG.

As shown in FIGS. 1, 3A and 3B, the valve body 110 includes a steam inlet 111 serving as an inlet passage for steam, and a steam outlet 112 serving as a drain passage for the introduced steam. do.

The steam supply part 100 includes an electronic steam flow path opening / closing part 120 having a solenoid valve 600 installed in the steam inlet part 111 to intermittently supply steam.

2 and 3A, the electronic steam flow path opening / closing part 120 includes a stem guide 121 inserted into an upper portion of a valve body 110 provided with a steam inlet 111, A stem 122 inserted into the interior of the valve body 110 through the valve body 110 and exposed to the outside of the valve body 110 and a stem 122 provided inside the valve body 110 and partially A valve cone 125 which is coupled to the stem 122 by a stem fixing member 124 and a locking plate 124a to open and close the steam inlet 111, And a pressure control disk 140 which is provided in the interior of the body and is locked and adjusted by the lock bolt 141 and the lock screw 142.

The solenoid valve 600 is connected to the upper end of the stem 122 and is electrically opened and closed by a separate control circuit unit (not shown) to thereby open and close the steam inlet 111.

For reference, the magnetic valve 600 is also referred to as a solenoid valve, which receives a signal current by a temperature regulator or a pressure regulator, and automatically opens and closes the valve using the electromagnetic force of the electromagnetic coil.

In this embodiment, it is preferable to apply a solenoid valve for steam, and an automatic type and a pilot type can be selectively applied according to the opening and closing operation of the valve.

In addition to the needle valve, the pilot type is used to operate the servo piston by using fluid pressure, and can be applied to a case where the steam supply amount is large and the pressure is high.

When the electromagnetic valve 600 is powered by a control circuit (not shown) when the steam supply is required, the operation of the electromagnetic steam flow control unit 120 configured as described above is performed by the electromagnetic coil of the electromagnetic valve 600, 601 are moved down so that the stem 122 and the valve cone 125 connected thereto are moved to open the steam inlet 111 to supply steam. At this time, the coil spring mounted on the operation rod is in a compressed state.

On the contrary, when the electromagnetic valve 600 is powered off, the electromagnetic force of the electromagnetic coil is canceled, so that the operating rod is returned to its original position by the coil spring, and the valve cone 125 is also moved upward by the pressure of the steam, The inlet 111 is closed.

Meanwhile, the rotary sleeve pipe 200 has a structure in which one side is rotatably connected to the steam supply unit 100 and the other side is connected to the inside of the combustion structure (BS).

In addition, a plurality of spray nozzles 40 are mounted on the rotary sleeve tube 200 on the entire outer surface at intervals to spray steam in the form of a screw.

1 to 4, the rotary sleeve pipe 200 includes a motor bracket 610 provided on the valve body 110 in which the steam outlet 112 is located, and a motor bracket 610 provided on the motor bracket 610, A drive gear 630 detachably coupled to the rotary sleeve 200 and rotated by gearing with the drive motor 620 and a drive gear 630 coupled to the motor bracket 610 in a detachable manner (Not shown).

The motor bracket 610 may be detachably bolted to the valve body 110 provided with the steam inlet 111 as shown in FIGS.

The driving motor 620 may be detachably and boltably coupled to the motor bracket 610 and a motor shaft 621 may be provided on one side of the driving motor 620. The motor shaft 621 may be provided with a driving gear 630, A motor gear 622 is provided.

The motor gear 622 provided on the motor shaft 621 is meshed with the driving gear 630 so that the driving gear 630 is also rotated to rotate the motor shaft 621, The sleeve nozzle 200 rotates together with the injection nozzle 40 so that the steam of high temperature and high pressure is evenly injected in the combustion chamber so that the soot layer S attached to the surface of the combustion chamber W and the surface of the heat exchange pipe P, To remove the layer (C).

The drive gear 630 is provided with a through hole through which the rotary sleeve tube 200 passes at its center, and gear teeth are continuously provided on the outer peripheral surface thereof, such as a flywheel.

The electromagnetic valve 600 of the electronic steam flow path opening and closing part 120 is mounted on the outside of the steam inlet 111 so that the operating rod 601 of the solenoid valve 600 is connected to the upper end of the stem 122, 600 are electrically connected to a control circuit (not shown) together with a driving motor so as to be interlocked when steam is supplied.

That is, when the solenoid valve 600 is operated and the stem 122 opens the steam inlet, the driving motor is operated to rotate the rotary sleeve tube 200, and the steam of high temperature and high pressure is injected into the combustion chamber through the injection nozzle 40 Evenly.

The ozone generating device 30 and the air supplying device 20 are also operated by the control circuit part to selectively supply ozone of 0.01 PPM to 1 PPM together while supplying outside air into the combustion chamber, Is configured to exert an oxidizing action to prevent removal and reattachment of layer (C).

Accordingly, in the present invention, the soot layer (S) is removed by high-temperature and high-pressure steam, and the scale layer (C) containing sulfur oxide in the lower part of the soot layer (S) 9B, the scale layer C can be more easily removed and the reattachment of the soot and the scale layer C can be prevented.

When the solenoid valve 600 is operated as described above, the stem 122 is also pressed downward and descends downward with reference to FIG. When the stem 122 is lowered, the valve cone 125 connected to the stem 122 is also lowered to open the steam inlet 111, so that the steam can be supplied to the rotary sleeve tube 200.

3 and 4, the upper portion of the base bracket 700 is detachably bolted to the motor bracket 610 to support the rotary sleeve tube 200 and the connection of the wall box 800 Place.

In this embodiment, the lower portion of the base bracket 700 can be detachably bolted to the valve body 110, as shown in Fig.

A thrust bearing B may be provided between the base bracket 700 and the drive gear 630 as shown in FIG.

The injection nozzle 40 is a first type,

A fixing part 41 welded to the coupling hole 202 formed in the outer circumferential surface of the rotary sleeve tube 200 by welding or screwing and having a coupling hole 42 in the center thereof, A nozzle body 45 having a plurality of through holes 43 formed radially and a seating portion 44 provided on the upper portion of the through hole 43; And a curved portion 47 and an inclined portion 48 extending outwardly from the coupling portion 46. The coupling portion 46 is formed at the center of the through hole 43 so as to be adjustably screwed up and down, And a nozzle head 49 for forming a steam discharge port between the inclined portion 48 and the seating portion 44.

According to the present invention, the injection nozzle 40 is a second embodiment,

A fixing part 41 welded to the coupling hole 202 formed in the outer circumferential surface of the rotary sleeve tube 200 by welding or screwing and having a coupling hole 42 in the center thereof, A nozzle body 45 having a plurality of through holes 43 formed radially and a seating portion 44 provided on the upper portion of the through hole 43; A coupling part 46 which is assembled to move up and down in the center of the through hole 43 and a curved part 47 and an inclined part 48 which extend outward from the coupling part 46, A nozzle head part 49 forming a steam discharge port between the seat part 48 and the seat part 44; A resilient member (70) assembled to the outside of the fastening part (46) so that the nozzle head part (49) is downwardly collapsed; And a fixing member 71 fixed to the coupling portion 46 to support the elastic member 70. [

According to the above-described first and second embodiments, as shown in Fig. 5, the through-holes 43 of the first and second embodiments have a common configuration in which the outlet from the inlet is directed toward the fastening hole 42 And may be inclined inward.

In addition, when the nozzle body 45 is welded to the coupling hole 202, the nozzle body 45 maintains a solid state when high-pressure steam is injected.

As another form, when the nozzle body 45 is screwed, the nozzle body 45 can be detached or coupled to the engagement hole 202, so that various types of the injection nozzles 40 can be replaced and applied, It offers the advantage of being easy to replace.

In addition, the fastening portion 46 and the fastening hole 42 of the nozzle head portion 49 of the first embodiment can be constrained and screw-assembled. Especially, when the fastening portion 46 and the fastening hole 42 are screwed together, the interval between the steam discharging holes D can be adjusted to vary the steam injection amount and the spray shape.

At this time, it is preferable that at least one loosening preventing nut is assembled to the end of the fastening part 46 to prevent the nozzle head part 49 from being loosened.

Since the nozzle head 49 of the second embodiment is assembled so as to be movable up and down in the fastening hole 42, the nozzle head 49 is always kept closed when a resilient member such as a coil spring is mounted When the steam is supplied into the rotary sleeve 200, the nozzle head 49 moves upward while compressing the coil spring, so that the steam discharge opening D is opened and steam is sprayed.

When the supply of steam is stopped by the solenoid valve 600, the nozzle head 49 is returned to the elastic member (coil spring) and the nozzle body 45 is seated in the seating portion 44 of the nozzle body 45, Lt; / RTI >

According to the spray nozzle 40 of the present invention, the steam is supplied through the rotary sleeve tube 200 and then divided into the nozzle head 49 through the plurality of through holes 43, The steam passing through the through hole 43 can be injected at a high pressure by raising the internal pressure.

Accordingly, immediately after passing through the through hole 43, the steam is guided by the curved surface portion 47 and the inclined portion 48 of the nozzle head portion, and is diffused outward while being diffused.

5, the through holes 43 of the first and second embodiments are formed such that the outlet from the inlet is inclined inward toward the coupling hole 42, so that the steam is guided in an inclined direction in the spiral direction, In the process of passing through the through hole 43, the steam is spirally twisted and sprayed as a whole.

Such a spray shape provides an effect of effectively removing soot and scale by a spraying force that is injected in a helical shape rather than a conventional spraying method in which a straight shape is sprayed in order to remove soot and scale inside the combustion chamber.

7A, the injection nozzle 40 may be formed symmetrically with respect to the central axis of the rotary sleeve tube 200, and may have a triangular shape and a rectangular shape as shown in FIGS. 7B and 7C. As shown in FIG.

According to this structure, when the rotary sleeve tube 200 is rotated by the driving motor, the interval between the steam injected at high pressure and the scale attached to the combustion chamber wall or the heat exchange pipe P is narrowed.

7A and 7C rather than the configuration of the spray nozzle 40 of FIG. 7A, the time for spraying the steam is shortened as the gap is narrowed, so that steam is frequently sprayed on the soap layer and the scale layer, And can be effectively removed.

8, the injection nozzle 40 according to the present invention is welded (E) to the coupling hole 202 as shown in FIG. 8 as a third embodiment, and the fixing portion 41 of the nozzle body 45 is formed on the inner peripheral surface thereof. And a detachable member (60) having a threaded portion (61) to be screwed onto the screw.

According to this construction, since the detachable member 60 is welded to the rotary sleeve tube 200, the nozzle body 45 and the detachable member 60 can be easily replaced and maintained by screw assembly.

Accordingly, it is possible to appropriately replace various types of injection nozzles 40 according to the shape of the combustion chamber, and it is possible to easily replace the nozzles when the nozzles are broken.

4, a rotary sleeve pipe 200 'according to another embodiment of the present invention includes a first sleeve pipe 201 rotatably connected to the steam supply unit 100, The first sleeve tube 201 and the second sleeve tube 300 are separated from each other by the second sleeve tube 300 having the injection nozzle 40 connected to the inside of the first sleeve tube BS, Can be combined.

In this way, the rotary sleeve pipe 200 'is configured such that one side of the first sleeve pipe 201 is coupled to the steam outlet 112 of the valve body 110 and the other side is slightly drawn into the combustion structure BS The steam introduced into the valve body 110 of the steam supply unit 100 is discharged to the inside of the combustion chamber through the injection nozzle 40 of the second sleeve pipe 300 by being detachably coupled to the second sleeve pipe 300 will be.

According to the present invention, a first flange 210 is provided at one end of the first sleeve tube 201 as shown in FIG. 4, and at one end of the second sleeve tube 300, And the second flange 210 is coupled to the first flange 210 and the second flange 210 is coupled to the first flange 210. The coupling region of the first flange 210 and the second flange 310 is provided inside the combustion structure BS .

In this embodiment, the first flange 210 can be screwed to be detachable from the first sleeve tube 201, and a plurality of the first flange 210 can be coupled to the second flange 310 of the second sleeve tube 300, A plurality of coupling protrusions 220 may be provided at predetermined intervals.

4, a gland G is provided between the rotary sleeve pipe 200, 200 'and the steam discharge port 112 in the present embodiment, and the rotary sleeve pipe 200, 200' (200, 200 ') may be fixed to the valve body (110).

4, the second sleeve tube 300 is disposed inside the combustion structure BS and is coupled with the first sleeve tube 201 to guide the steam into the combustion structure BS And the steam is supplied to the injection nozzle 40.

4, a second flange 310 is provided at the end of the second sleeve tube 300 in contact with the first sleeve tube 201 in the present embodiment, 1 flange 210 is provided with a plurality of fastening holes so that both can be bolted to each other.

The second flange 310 facing the first flange 210 is provided with a coupling groove 320 as shown in FIG.

Since the second sleeve pipe 300 and the first sleeve pipe 201 are coupled to each other by the butt-bolting method using a flange rather than a coupling or a socket as in the present embodiment, the separation of the second sleeve pipe 300 So that maintenance of the second sleeve pipe 300 can be facilitated.

Since the distance between the first flange 210 and the second flange 310 can be adjusted by adjusting the degree of tightening of the bolt, it is possible to prevent leakage, and the distance between the first flange 210 and the second flange 310 It is possible to more effectively prevent leakage of steam.

According to an embodiment of the present invention, there is further provided a packing unit 400 provided at a coupling region of the rotary sleeve pipe 200, 200 'and the steam supply unit 100. The packing unit 400 includes a plurality of And the packing member of the first embodiment can be fitted and fitted to each other.

3A and 4, the packing unit 400 is provided in the steam discharge port 112 of the valve body 110 to which the one end of the rotary sleeve pipe 200 or 200 'is coupled, and the rotary sleeve pipe 200 or 200' And serves to prevent steam from leaking into the space between the steam exhaust ports 112.

3B, the packing unit 400 includes a pair of first packing members 410 disposed at the outermost positions, and a pair of first packing members 410 disposed between the pair of first packing members 410 And a plurality of second packing members (420).

6, in the region where the pair of first packing members 410 and the plurality of second packing members 420 are in contact with each other in the present embodiment, and in each of the plurality of second packing members 420, The grooves 400a are provided so that the pair of first packing members 410 and the plurality of second packing members 420 can be interference fit through the fitting grooves 400a.

In this embodiment, the fitting groove 400a may be provided in the shape of a letter "V ". In this case, since the fitting region 400a is enlarged when the respective packing members are engaged, There is an advantage that the leakproofness and the product life are improved as compared with the grand packing.

The pair of first packing members 410 may be made of a metal material and the plurality of second packing members 420 may be made of a rubber material.

And a bushing member provided with the packing unit 400 in a coupling region of the rotary sleeve pipe 200, 200 'and the steam supply unit 100.

4, the bushing member 500 may be provided at the steam outlet 112 adjacent to the packing unit 400, but at a position prior to the packing unit 400. As shown in FIG.

The bushing member 500 of this embodiment is not applied to the previous blower. In the present embodiment, the bushing member 500 is provided to prevent corrosion and rotation of the rotating sleeve pipe 200, 200 'due to moisture, foreign matter, It is possible to prevent the steam from leaking and to help smooth rotation of the rotary sleeve 200 or 200 '.

In this embodiment, the bushing member 500 may be made of a brass material.

4, one side of the wall box 800 is detachably bolted to the base bracket 700 and the other side of the wall box 800 is detachably coupled to the wall W of the combustion structure BS Thereby supporting the rotary sleeve tubes 200 and 200 'and sealing the combustion structure BS to prevent the harmful gas from coming out of the atmosphere.

The wall box is provided between the steam supply unit 100 and the combustion structure BS so as to rotatably support the rotary sleeve 200 or 200 'and is provided at one side with the outside air of the combustion structure BS, And an air inlet pipe for introducing the air into the interior of the BS.

The wall box 800 is detachably bolted to one side of the base bracket 700 while the other side of the wall box 800 is detachably coupled to the wall W of the combustion structure BS so as to be rotatable about the rotation sleeve pipe 200, And serves as a seal to prevent the harmful gas inside the combustion structure (BS) from coming out of the atmosphere.

4, the wall box 800 includes a box body 810 having one side thereof detachably bolted to the wall W of the combustion structure BS, a box body 810 detachably coupled to the wall W of the combustion structure BS, An air inlet pipe 820 provided in the outer side of the box body 810 for introducing outside air into the interior of the box body 810 and air introduced through the air inlet pipe 820 in a spiral form And a helical guide member 830 for introducing the fuel into the combustion structure BS.

The rotary sleeve tubes 200 and 200 'penetrating into the box body 810 of the wall box 800 can be fixed by the gates G as shown in Fig. In this embodiment, the ground G may be made of cast steel or SS400 (S41) steel to prevent cracking due to weak abrasion resistance and durability.

The air introduced through the air inlet pipe 820 may be opened to the inside of the combustion structure BS to the box body 810 in contact with the wall W of the combustion structure BS in this embodiment.

The air inlet pipe 820 of the wall box 800 may be provided in the box body 810 in the region adjacent to the wall W of the combustion structure BS as shown in FIG.

The present invention may further include a helical guide member provided in the wall box 800 and spirally rotating the air introduced through the air inlet pipe to introduce the air into the combustion structure BS.

The helical guide member 830 of the wall box 800 may be provided on the lower side of the air inflow pipe 820 as shown in FIG. 4, and the inflow air is spirally rotated, cooled, To the inside of the structure (BS).

In this embodiment, the helical guide member 830 includes a member capable of rotating the inflow air such as a coil spring in a spiral shape.

Meanwhile, the mineral catalyst member 50 is installed in a connection pipe 51 connected to the steam channel openings, and contacts the steam to discharge (-) electrons into the combustion chamber to effectively remove the soot and scale.

In addition, according to the present invention, the mineral catalyst member 50 may have a porous structure having tourmaline as a main component and a cylindrical shape including a plurality of steam passing holes.

The steam passing holes are formed in a rectangular shape, a circular shape, and a hexagonal shape, and are formed so as to pass through in the longitudinal direction.

The reason why tourmaline is used in removing the soot layer (S) and the scale layer (C) in the present invention is as follows.

Tourmaline is the source of the most (-) electrons generated from natural stone. (-) electrons are generally supplied with steam consisting of vaporized water, which is very excellent for interfering with the binding of the soot layer (S) and the scale layer (C) or breaking the molecular bonding rings connected thereto. I. E. Hydroxyl function or surfactant action.

As shown in FIG. 9B, since the mineral catalyst member 50 is continuously supplied with the (-) electrons emitted by the contact of the steam, such as tourmaline, in the steam, it is formed on the inner wall of the combustion chamber or on the surface of the heat exchange pipe It is very effective in decomposing and removing the soot layer S and the scale layer C and has a function of preventing corrosion of the inner wall of the combustion chamber and the heat exchange pipe P by the soot layer S and the scale layer C .

In other words, the (-) electrons are continuously generated by the tourmaline to interfere with the binding of the sulfur oxides generated in the soot and the combustion process, thereby decomposing and removing the scales already generated, and preventing further generation of scales.

The ozone generator 30 is connected to the air inlet pipe of the wall box to supply a small amount of ozone to facilitate the removal of the soot and the scale layer C, The effect of sterilization is exerted.

According to the present invention, the ozone concentration supplied from the ozone generator 30 is preferably 0.01 PPM to 1 PPM.

Ozone which is supplied together with the outside air into the combustion chamber is highly effective in removing impurities, harmful components and odors remaining in the combustion chamber because it is sterilizing and deodorizing because of its strong oxidizing power.

According to the present invention, the entire outer surface of the rotary sleeve tube 200, 200 'may include a heat-resistant coating layer, and the heat-resistant coating layer may be formed of a spray coating layer having a surface roughness of 3 to 8 RMS.

Accordingly, since the suet and the scale are not attached to the outer surface of the rotary sleeve tubes 200 and 200 ', the rotary sleeve tubes 200 and 200' can be used for a long period of time without frequent replacement.

Hereinafter, the operating state of the present embodiment will be briefly described.

3A and FIG. 4 show a state in which the valve cone 125 blocks the steam inlet 111 and the steam is not supplied to the second sleeve tube 300.

When the solenoid valve 600 is operated in this state, the stem 122 connected to the operating rod is also pressed downward so that the valve cone 125 connected to the stem 122 is also moved downward to move the steam inlet 111, Lt; / RTI >

Accordingly, the supplied steam moves along the steam inlet 111 and the rotary sleeve tubes 200 and 200 'and is supplied to the inside of the combustion structure BS, and the spray nozzles 40 provided in the rotary sleeve tubes 200 and 200' So that the soot and scale can be removed.

As described above, in the present embodiment, the rotary sleeve pipe 200 'is detachably bolted to the second sleeve pipe 300 by the first sleeve pipe 201 so that the second sleeve pipe 300 is convenient The second sleeve tube 300 can be easily serviced and leakage can be prevented in the coupling region of the first sleeve tube 201 and the second sleeve tube 300, It is possible to prevent the sleeve tube 300 from being deformed.

The bushing member 500 is additionally provided in the steam outlet 112 of the present embodiment so that corrosion of rotating sleeves 200 and 200 'due to moisture and foreign substances introduced into the inside of the rotating sleeve pipes 200 and 200' Can be prevented from occurring and it is possible to assist the rotation operation of the rotating sleeve pipe 200, 200 '.

Furthermore, in the present embodiment, the packing part 400 provided in the steam outlet 112 may be formed of a plurality of packing members having grooves of a "V" shape instead of a square shape, thereby improving leak tightness and product life.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention may be embodied otherwise without departing from the spirit and scope of the invention.

Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

1: soot blower device 10: steam supply device
20: air supply device 30: ozone generator
40: injection nozzle 41:
42: fastening hole 43: through hole
44: seat part 45: nozzle body
46: fastening part 47: curved part
48: slope part 49: nozzle head part
50: Mineral catalyst member 51: Connection piping
60: detachable member 61: threaded portion
70: elastic member 71: fixing member
100: steam supply unit 110: valve body
111: steam inlet 112: steam outlet
120: Electronic steam flow opening / closing part
121: Stem Guide 122: Stem
123: valve seat 124: stem fixing member
125: Valve cone
140: Pressure control disk 141: Lock bolt
142: Rock screw 200, 200 ': Rotating sleeve pipe
201: first sleeve tube 202: engaging hole
210: first flange 220: engaging projection
300: second sleeve tube 310: second flange
320: coupling groove 400: packing part
410: first packing member 420: second packing member
500: bushing member 600: solenoid valve
610: motor bracket 620: drive motor
621: motor shaft 622: motor gear
630: drive gear 650: safety cover
700: Base bracket 800: Wall box
810: box body 820: air inlet pipe
830: helical guide member B: thrust bearing
BS: Combustion structure D: Steam outlet
E: Welding G: Grand
P: heat exchange tube W: wall
C: scale layer S: soot layer

Claims (17)

A steam supply unit disposed outside the combustion structure to supply steam into the combustion structure;
An electronic steam flow path block provided in the steam supply line and having an electromagnetic valve for controlling steam supply;
A rotary sleeve pipe rotatably connected to the steam supply part at one side and connected to the inside of the combustion structure at the other side;
A plurality of spray nozzles mounted on the rotary sleeve tube at an interval on the entire outer surface thereof for spraying steam in the form of a screw;
A wall box provided between the steam supply unit and the combustion structure for rotatably supporting the rotary sleeve tube and having an air inlet pipe for introducing outside air of the combustion structure into the combustion structure;
A mineral catalyst member mounted in a pipe connected to the electronic steam flow path portion and contacting with the high temperature and high pressure steam to emit (-) electrons; And
And an ozone generator connected to the air inlet pipe to supply a small amount of ozone. The method according to claim 1,
Wherein the mineral catalyst member is a porous structure having tourmaline as a main component and includes a plurality of steam passing holes. The method according to claim 1,
Wherein the ozone concentration supplied from the ozone generating device is 0.01 PPM to 1 PPM. The method according to claim 1,
Wherein the rotary sleeve pipe is divided into a first sleeve pipe rotatably connected to the steam supply unit and a second sleeve pipe connected to the combustion structure and having the injection nozzle,
Wherein the first sleeve tube and the second sleeve tube are detachably bolted to each other. ≪ RTI ID = 0.0 > 15. < / RTI > The method of claim 4,
A first flange is provided at one end of the first sleeve tube,
Wherein a second flange is provided at one end of the second sleeve tube and corresponds to the first flange and is bolted to the first flange,
And a joint region of the first flange and the second flange is provided inside the combustion structure. The method according to claim 1,
The spray nozzle
A fixing portion having a fastening hole formed in the center thereof by being welded or screwed to an engaging hole formed in the outer peripheral surface of the rotary sleeve tube; a plurality of through holes formed radially around the fastening hole; A nozzle body; And
And a nozzle head portion formed of a curved portion and an inclined portion extending outwardly from the coupling portion and forming a steam discharge port between the inclined portion and the seating portion, And a sucking device for sucking and discharging the sucked air. The method according to claim 1,
The spray nozzle
A fixing portion having a fastening hole formed in the center thereof by being welded or screwed to an engaging hole formed in the outer peripheral surface of the rotary sleeve tube; a plurality of through holes formed radially around the fastening hole; A nozzle body;
A nozzle head part formed of a curved part and an inclined part extending outwardly from the coupling part to form a steam discharge port between the inclined part and the seating part;
An elastic member which is assembled to the outside of the fastening portion so as to elastically collapse the nozzle head portion; And
And a fixing member fixed to the fastening portion to support the elastic member. The method according to claim 6 or 7,
Wherein the through hole is inclined in a spiral direction while an outlet from the inlet is formed to be inclined inward toward the fastening hole, wherein the sole and the scale can be easily removed. The method according to claim 6 or 7,
Further comprising a detachable member welded or screwed to the coupling hole, the detachable member having a threaded portion screwed into the fixing portion of the nozzle body on an inner circumferential surface thereof. The method according to claim 1,
And a packing portion provided in a coupling region of the rotary sleeve tube and the steam supply portion, wherein the packing portion is provided by fitting a plurality of packing members, each having a fitting groove, to each other. Soot blower device. The method of claim 10,
The packing portion
A pair of first packing members each disposed at an outermost periphery; And
And a plurality of second packing members provided between the pair of first packing members, and the sole can be removed easily. The method of claim 10,
Wherein the fitting groove is provided in an area where the pair of first packing members and the plurality of second packing members are in contact with each other so that the pair of first packing members and the plurality of second packing members are held together And the sucked air is sucked into the sucking port. The method of claim 10,
Wherein the pair of first packing members are made of a metal material,
Wherein the plurality of second packing members are made of a rubber material. The method of claim 9,
And a bushing member provided at the coupling region of the rotary sleeve tube and the steam supply unit together with the packing unit. The method according to claim 1,
And a spiral guide member provided in the wall box for spirally rotating the air introduced through the air inlet pipe and introducing the air into the combustion structure. The method according to claim 1 or 4,
And a heat-resistant coating layer is formed on the entire outer surface of the rotary sleeve tube. 18. The method of claim 16,
Wherein the heat-resistant coating layer is a spray coating layer having a surface roughness of 3 to 8 RMS.

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