FI124353B - Muffler for a flue gas duct of a combustion boiler and combustion boiler - Google Patents

Description

FIELD OF THE INVENTION The invention relates to a silencer structure of a combustion flue for a combustion boiler. The invention further relates to a combustion boiler.

BACKGROUND OF THE INVENTION Combustion boilers burn combustible material to produce energy. An example of a prior art combustion boiler 100 is shown in side elevation in Figure 1a. The boiler comprises a furnace 110 in which combustible material is burned and a passage 112 for supplying combustion air 150. The combustion process generates heat in the furnace that is recovered from the flue gases and radiation. The heat can be recovered, for example, by superheaters 120 on the top of the furnace. From the furnace, the flue gases are introduced into the flue gas duct. Heat from the flue gas duct can be recovered by evaporators 130. Superheaters 120 and evaporators 130 typically comprise heat exchanger tubes 122 and 132, respectively, for recovering heat. Heat can be recovered, for example, into 20 water or steam. Further, the water may be preheated in the water preheating area 200. In addition, heat may be recovered in the combustion air 150 in the air preheating area 250. The cooled flue gases 160 may be removed from the process. For example, the smoke salt 300 between the water preheating area 200 and the air preheating area 250 may have support structures for, for example, water and air preheater. In addition, the front wall 302 and the back wall 304 of the flue gas duct are shown in the figure. The flue duct may have a substantially rectangular shape in the cross sectional plane 301 perpendicular to the flow direction of the flue gases; it may comprise a substantially perpendicular flue gas stream. Similarly, the smoke preheating area 200 may comprise a front wall c0 202 and a rear wall 204. Accordingly, the air preheating area 250 may comprise a front wall 252 and a rear wall 254. Figure 1b illustrates a front wall 202, a rear wall 202, a first side wall 206, and a second side wall 208. | mutual location.

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One problem with prior art combustion boilers is the sound they produce. The resulting sound is typically between about 40 Hz and about 100 o Hz. The sound is typically tonal, that is, the sound is strongest at or near a certain frequency. This particular frequency may be influenced, for example, by the dimensions of the boiler or flue gas duct.

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For example, tonal sound differs from noise, where vibration occurs at substantially the same intensity over a wide frequency band.

Figure 2a illustrates in more detail a side view of the water preheating area 5200. One possibility of a sound source is the turbulence of the flue gas flow. The turbulence is caused, for example, by the water preheaters 210 in the water preheating area 200. The preheaters 210 can be, for example, pipe packages. Figure 2b illustrates the tube in more detail as another side view, substantially perpendicular to Figure 2a. The tube packages comprise heat exchanger tubes 212. As shown in Figures 2a and 2b, tubes 212 may extend from the front wall 202 to the rear wall 204. The turbulence may also be affected by air preheaters 260 in the air preheating area 250.

Figures 2c and 2d illustrate air preheaters 260, which may also be tubular packages comprising tubes 262. Figure 2c shows arrows 150 of combustion air in the air preheater. Also, air preheating tubes 262 may extend from the front wall 252 of the air preheating area 250 to the rear wall 254. The air preheating tubes 262 are located between the side walls 256 and 258 of the air preheating area 250.

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Prior art is described in JP2001108227. The publication discloses a flue gas duct with a circular cross section, lined with silencer plates on the inside.

According to the prior art, the noise of combustion boilers can be attenuated by plates arranged in a flue gas hose. For example, the plates may be metal plates which are intended to influence the formation and wavelength of the standing sound wave. However, the prior art has not achieved sufficient attenuation. In some solutions, placing the plates in the flue gas duct 30 makes it difficult to clean the flue gas duct.

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BRIEF SUMMARY OF THE INVENTION It has been found that the noise from combustion boilers can be attenuated by placing a bar of substantially flue gas absorbing muffler plates in the flue gas duct so that at least two muffler plates are angled to each other. Sound-absorbing δ-plates effectively reduce noise. Placing the plates at an angle of 00 to each other reduces the width of the resonating region. Placing the plates substantially in the flue gas flow direction facilitates sweeping.

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According to one embodiment, the silencer comprises a service passage through which the flue gas duct, silencer plates or silencer can be maintained, for example, cleaned.

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According to one embodiment, the muffler plates cut off the resonant region of the flue gas duct, thereby eliminating the low frequency resonance length.

10 Description of the drawings

The invention will now be described in more detail with reference to the accompanying drawings, in which Figure 1a shows a side view of a prior art combustion boiler, Figure 1b shows the front, rear, and side walls of the water preheating area. Fig. 3a is a vertical view of an embodiment of a silencer; embodiment,

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Fig. 3e is a vertical view of a fourth embodiment of a silencer, Figs. 4a and 4b show two side views of a silencer plate, Figs. 8a and 8b illustrate a vertical view of some embodiments of the silencer.

Figures 1-8 use numbers or symbols corresponding to the corresponding parts.

Detailed Description of the Invention

Fig. 3a shows a cross-section of the flue gas duct in a plane substantially perpendicular to the direction of flow of the flue gases. The flue gas duct has a width of 1/1 / and a depth L of 1/1 / may be several meters, 20 between 4 and 12 m, and for example about 8 m. Depth L can be several meters, between 2 and 5 m, and e.g. about 3.5 m. In toning boilers, the general tonal noise may be generated by the resonance formed between the substantially parallel walls of the flue gas duct. Thus, the distance between the parallel surfaces may be a multiple of half a wavelength. For example, in Figure 3a, the longest resonating wave 310 is twice the length of the flue gas channel 1/1 /, whereby the width W corresponds to half the wavelength (λ / 2). The following resonance frequency can occur when the wavelength λ corresponds to the width of the flue gas channel 1/1 /. The resonance frequencies are significantly influenced by the flue gas surface of the flue gas, which can influence the wave reflection. If the boundary conditions from the surface are not taken into account, the relation between the wavelength λ at resonance g and the flue gas channel W can be deduced: W = nX / 2 integer (1, 2, 3, ...) As is known, the frequency of the sound depends on the speed and wavelength of the sound: f = vlX. From these starting points a connection can be made to the frequency of the sound in the resonance and the flue gas channel: * 35 CM j. LO f = -.

LO 1 2 W

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00 Several resonance frequencies corresponding to different values n can be calculated from the equation.

Correspondingly, in the depth direction of the flue gas channel, possible resonance frequencies of f = nv / 2L can be deduced. The speed of sound depends on the density and pressure of the gas. As the density increases, for example as the temperature decreases, the speed of the sound decreases. Thus, in a hot flue gas duct, the speed of sound may be higher than at room temperature. The speed of sound affects the resonance frequency as described above. Typically, after the water preheater, the flue gas temperature in the flue gas is about 250 ° C. According to one approximation, the speed of sound in hot air is 343 m / s + 0.6 m / s ° C (T-20 ° C), where T is the temperature in degrees Celsius. According to this approximation, the speed of sound in, for example, 250 ° C air would be about 480 m / s. As the speed of the sound decreases, the resonance frequency also decreases, since, as described above, the resonance frequency is directly proportional to the speed of the sound. At the said speed of sound 480 m / s, an 8 m wide channel can resonate e.g. at 30 Hz, and multiples of this. Correspondingly, a 3.5 m deep canal can resonate e.g. at 69 Hz and multiples of this. The frequency of the observed noise is typically in the range of 40-100 Hz, which may correspond to width resonance at some resonant frequencies (n = 2 or 3) or depth resonance at some other resonance frequencies (n = 1).

It is possible that there is no resonance in the longitudinal direction of the flue gas channel (from top to bottom in Figure 2a-2d) since in this direction the flue gas channel may also comprise non-parallel reflecting structures. Referring to Figures 1 and 2, for example, heat exchanger tubes 212 and 262 may prevent resonance in the longitudinal direction of the flue gas duct.

25 Noise can be reduced with a silencer. The silencer may comprise one or more silencer plates. The sound can also be dampened with vibration dampers. For example, noise of a certain frequency can be reduced by, for example, attenuating the noise with the muffler plates and / or changing the lengths of the structure so that the resonant frequency changes. For example, the silencer discs may reduce the width of the resonating region. The muffler discs can also cut the resonant region completely, i.e., shorten the resonant length. In this case, there is no perpendicular line of sight between the walls of the two parallel smoke ducts. The muffler plates can narrow the area in said width direction or “35 in said depth direction or both. Similarly, the muffler plates can shorten the resonant length in said vein or in said depth direction, or both.

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Figure 3b shows one embodiment of the silencer to the flue gas duct of the boiler. In the figure, the silencer is shown in a vertical view and 6 is disposed in the smoke salt 300 of the flue gas duct (Figure 1a). Although the silencer in the figure is located precisely in the smoke salt 300, it is obvious that the silencer according to the invention can also be located elsewhere in the flue gas duct. In particular, the silencer according to the invention may also be located elsewhere than at the expected noise source. Noise can be generated, for example, by vortexes caused by heat exchanger pipes, but there are no heat exchanger pipes in the smoke passage. The muffler may be located just in the smoke passage 300 after the water preheating area 200. The muffler may be located downstream of the evaporator heat exchanger tubes 132 ίο. The muffler may also be located downstream of the flue gas, or alternatively, only after the water preheater heat exchanger tubes 212. Further, the flue gas duct may be provided with heat exchanger tubes 262 for the combustion air preheater, whereby the silencer may be located ahead of said heat exchanger tubes 262. Thus, the silencer may be located between the heat exchanger tubes (132, 212) and Multiple silencers may also be provided in the flue gas duct. Further, the silencer according to the invention may be located in the flue gas duct even in the flue gas flow direction before the heat exchanger pipes, or in the flue gas duct 20, which does not have the heat exchanger pipes.

For example, the first sidewall 306 may form part of the first sidewall of the flue gas duct 25 with the first sidewall 206 of the water preheating region (cf. Figures 1a and 1b). Correspondingly, the second sidewall 308 may form, for example with the second sidewall 208 of the water preheating region, as part of the second sidewall of the flue gas duct.

In the embodiment of Fig. 3b, the muffler comprises muffler plates 320. The muffler plates 320 are substantially planar and parallel to the direction of flow of the flue gases. In the combustion salt 300 of the combustion boiler 9 shown in Figure 1a, the flow direction of the flue gases is substantially from top to bottom.

o This orientation of the discs facilitates the cleaning of the flue gas duct and muffler discs. The muffler discs 320 comprise sound-absorbing materials.

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to The muffler discs 320 are intended to reduce especially low frequency g noise. As a result, the silencer plates 320 may be positioned such that the width of the resonance region is perpendicular to 00 the maximum resonant length of the flue gas channel and 40 perpendicular to the direction of flow of the flue gases. The width can be limited by placing the muffler plates at an angle to each other; for example, by placing two plates at an angle to each other. In the flue gas duct of Figure 3a, the maximum resonant length is 1/1 / of the flue gas duct width. Perpendicular to this and perpendicular to the direction of flow of the flue gases is the depth of the flue gas channel 5 in the figure.

In the silencer arrangement of Figure 3b, the silencer plates 320 are positioned such that the width of the resonance range perpendicular to the maximum resonant length of the flue gas channel and perpendicular to the flue gas flow direction is significantly limited. The limited resonance range is illustrated by reference numeral 352, at which point the flue gas channel can resonate with a width corresponding to 1/1 / its width, whereby the resonance frequency may be low. In the silencer of Fig. 3b, the silencer plates 320 are at an angle to each other, in particular plates 320b and 1520c are at an angle to the plates 320a. With muffler discs 320

is at an angle to each other, also perpendicular to the smallest resonant length and perpendicular to the flue gas flow direction, the width of the resonance range is limited. This limited resonance range is illustrated by reference numeral 350, at which point the fume-20 can also resonate with a depth L corresponding to its depth direction.

The placement of the muffler discs can influence how much the resonance range width is limited. The width of the resonance range can be limited in each direction perpendicular to the flue gas flow direction, for example, by at least 50%, at least 66%, or at least 75%.

In Fig. 3b, the width of the resonance range perpendicular to the maximum resonant length of the flue gas channel and perpendicular to the flue gas flow direction is limited to about 85%, i.e. the width of the resonating region le δ 30 is about 15% of the flue channel channel depth L. said resonance region is illustrated by reference numeral 352. In Fig. 3b, two other components are shown two above the wall 340 and two below the wall 340.

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3b, the width of the resonance region is also limited to about 85%, i.e., the width of the resonating region is about 15% of the width of the flue gas channel 1/1 /. One 00 part of said resonance range is illustrated by reference numeral 350.

A corresponding second portion is shown in Figure 3b to the right of wall 340.

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The silencer shown in Figure 3b comprises a wall 340 extending substantially in the middle of the flue gas channel in the direction of the sidewall (front wall 302 to the rear wall 304) of the flue gas, comprising silencer plates 320a. These silencer plates may be called the first silencer-5 plates 320a. Wall 340 is substantially perpendicular to said sidewall direction. In Figure 3b, some of the wall-forming plates are designated 320a. Further, the silencer may comprise silencer plates 320 which are substantially perpendicular to said wall. One such plate is designated 320b and 10 such is 320c. Such a plate 320b, which may be referred to as a second silencer plate 320b, may be closer to the wall 340 than the flue gas duct wall, or such plate 320c may be closer to the flue gas duct wall than wall 340, such a plate being called a third silencer plate 320c. In this case, the distance of the third silencer plate 320c from the wall 340 may be greater than the distance of the second silencer plate 320b from the wall 340.

Figure 3c shows another embodiment of the silencer. In the silencer shown in Fig. 3c, the resonating region is truncated along the width direction of the flue gas channel 20, thereby reducing the resonant length of the silencer plates. In particular, Fig. 3c shows the longest resonant length, which in a flue gas duct without a silencer would correspond to a width of 1/1 /. The muffler plates 320 are arranged such that there is no perpendicular line of sight between the parallel side walls 306 and 308 of the flue gas duct. Such a solution is achieved, for example, by arranging a portion of the silencer plates substantially perpendicular to the wall 340 against the wall 340. Such (other) plates are designated by reference numeral 320b. Similarly, a portion of the muffler plates substantially perpendicular to the wall 340 may be arranged on the wall of the flue gas duct, 30 Such (third) plates are designated 320c.

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Figure 3d shows a third embodiment of the silencer. In the silencer of Fig. 3d, the resonating region is truncated by smoke in the width direction of the gas duct, whereby the silencer discs have a shortened resonant length corresponding to the width. The baffle plates are thus arranged so that there is no perpendicular line of sight between the substantially parallel side walls 306 and 308 of the flue gas duct. In addition, the resonating region is truncated in the depth direction of the channel, whereby the muffler plates are shortened to the shortest resonant length corresponding to the depth. The sound attenuator plates 40 are thus arranged such that there is no perpendicular line of sight between the substantially parallel walls of the flue gas duct, front wall 302 and rear wall 304.

Figure 3e shows an embodiment of a silencer in a flue gas-5 duct which is substantially circular in a section perpendicular to the flue gas flow direction. In such a flue gas duct, one portion of the wall may be defined as a front wall 302 and a substantially parallel second portion of the wall to a rear wall 304. A resonating region 354 would be formed between these substantially parallel portions. In Fig. 3e 10, the silencer comprises two silencer plates 320 arranged at an angle to each other. Said angle may not be straight.

The silencer shown in Figures 3b to 3e comprises silencer plates 320 which are substantially in the direction of flue gas flow. It is possible that the flue gas flow direction is substantially horizontal, substantially vertical, or some other direction. Further, in a substantially vertical flue gas duct, the flow direction may be upward or downward.

The silencers shown in Figures 3b-3e further comprise a service passage 20 330. The service passage 330 is in a straight plane facing the flue gas flow direction. The muffler comprises two mutually angled flue gas baffle plates, said plane being substantially perpendicular to the muffler plates. The service passage 330 is bounded by the silencer baffle plates 320. Part 25 of the service corridor may be between the muffler plates 320 and a portion of the service corridor may be between the muffler plate 320 and the flue gas wall. At least one of the following can be serviced through the service corridor: muffler, muffler plate 320, and flue gas duct. Preferably, the silencer comprises only one service passage 330, whereupon this service corridor 30 should have access to the edges of the silencer (i.e., the walls of the flue gas duct) and the silencer plates 320 as shown in Figures 3b to 3e.

9 The silencer may also comprise a plurality of service corridors, for example if the flue gas duct is divided into separate areas by the silencer plates. In this case, the x shift between the service corridors may occur, for example, outside the silencer. Transition can occur either outside the flue duct or in the flue duct above or below the muffler. The silencer may also comprise a service platform 334 (Figure 6a), which serves as a base for the service passage 330. Also, the combustion boiler may comprise a service level 334 in its flue gas duct serving as a base for the silencer service passage 330 40. Other flue gas support structures can also be used to assist with maintenance.

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Preferably, the service aisle is so wide that the service person can pass along the service aisle. Preferably, the service aisle is at its narrowest point so wide that a service person can pass along the service aisle. By way of example, the narrowest point of the service corridor 330 is illustrated in Figure 3c 5 by reference numeral 332. The width of the service corridor from the narrowest point may be at least 40 cm, at least 60 cm or at least 80 cm. The service passageway may also be narrower in width than the muffler plate 320, whereby a portion of the resonating region comprising the service passageway may be cut by a single muffler plate. For example, the width of the service passage 332 illustrated in Figure 3c is smaller than the width of the silencer plate designated 320b. For example, the width of the muffler plate 320b may be 90 cm. Thus, for example, the width of the service corridor may be less than 90 cm. In particular, the width of the service corridor at its narrowest point may be approximately 50-80 cm.

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Figure 4a is a side view of one of the muffler plates 320 and Figure 4b is another side view of the same plate. The silencer plate 320 of Figure 4a comprises a first and a second side in the form of a plate. The silencer plate 320 comprises a core 322 between these sides, the core comprising 20 sound absorbing material. The core 322 may comprise, for example, a fibrous material such as soft mineral wool. Such a mineral wool may have a density of about 50 kg / m3. The silencer plate of Figure 4a further comprises a topsheet 326. The surface plate serves to reinforce the silencer plate and may be made of a wear-resistant material such as metal, for example 25 steel. The face plate 326 may reinforce the silencer plate against, for example, abrasion wear.

Preferably, the surface plate used in the silencer does not reflect sound. To prevent reflection, holes are provided in the surface plate as shown in Figure 4b. The surface area of the perforated surface plate 326 with respect to the corresponding aperture C \ \ For example, the surface area of the surface plate may be less than 75%, less than 50%, or less than 9% to 33%. Figure 4b is a front view of a surface plate 326 and of the surface plate holes showing an S joint layer 324. The joint layer 324 is connected to both the core 322 and the face plate x 326. The joint layer can be sound absorbing material or act as a support.

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35 nice between the face plate and the core. The bonding layer may comprise, for example, a mineral wool board. For example, the joint layer may have a thickness of 20 mm and a density of, for example, 250 kg / m3. The height hp ς of the muffler plate 320 may be, for example, between 1 and 5 m and, for example, about 3.5 m. The width wp of the muffler ™ plate 320 may be, for example, between 500 and 2000 mm, and for example about 900 mm. The thickness tp of the silencer plate 320 may be, for example, 100 to 500 mm, and for example about 300 mm. The effectiveness of the silencer may be affected by the amount of sound absorbing material therein, i.e., the thickness of the core 322 of the silencer plate 320, the height hp of the silencer plate, the wp of the silencer plate and the number of silencer plates 320 in the silencer.

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Flue gas ducts can be cleaned with a scrubber. The scrubber may operate, for example, with steam, whereby the steam discharged from the scrubber under pressure cleans the flue gas duct. The soot may, for example, be located at the bottom of the smoky salt 300, where it may be located below the muffler. Several flue gas ducts may be provided in the flue gas duct. The muffler plate 320 used in the silencer may be protected by a scrubber guard 328 (Fig. 4a). The shield may be, for example, a bent metal plate. The shield is closed at the bottom so that the steam from the scrubber does not reach the core 322 or the connection layer 324 of the muffler plate. The soother may also be provided above the muffler-15. The silencer plate 320 may also comprise a shield 328 (not shown) at its top.

Referring to Fig. 5a, the silencer plate 320 may not comprise a shield 328. The silencer plates may also be protected from scratch by placing them on an al-20 hook in a closed frame 500. The frame may also be top closed. Fig. 5a illustrates a side view of a silencer wall 340 between the side walls 306, 308 of the smoky salt, comprising silencer plates 320. Silencer plates 320 are arranged in a frame 500. Frame 500 is in turn supported by lower brackets 510 and above brackets 510. Each of the supports 510, 520 may serve as a support structure for the wall 340 and the other of the supports 520, 510 may serve mainly as a guide. All supports may also carry the silencer wall 340. For example, the lower supports 510 may support the frame 500, and thus the wall 340, with the overhead supports guiding to the top of the frame.

5 30 Similarly, the frame may hang on the overhead supports 520. In this case, the lower supports are not necessarily needed to guide the wall, but the wall 9 is guided by gravity to the correct position. The upper support structures 520 may be coupled to the water preheater support structures. The lower support structures 1 510 may be coupled to the support structures of the air preheaters. The silencer 35 may also be located elsewhere in the flue gas duct. The upper support structures 520 may then be connected to the air preheater support structures. Correspondingly, the support structures 510 below may be coupled to the support structures of the water preheaters 5. Either one of the support structures 510, 520 may be connected to the evaporator support structures if necessary.

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Figure 5b illustrates a frame 500 and a wall 340 in a sectional plane Vb-Vb of Figure 5a. The frame 500 may be in the form of a U-profile which opens towards the muffler plate 320. The muffler plate, in turn, is arranged in the channel of the frame, whereupon the frame 500 protects the muffler plates. The frame can protect the silencer discs from both the bottom and the top, as shown in Figure 5b.

Obviously, the above-mentioned silencer solution is suitable for use in various combustion processes in flue gas ducts. Especially the ίο solution is suitable for combustion boilers, such as power plant boilers. The combustion boiler according to the invention then comprises a silencer according to the invention in its flue gas duct. Correspondingly, the power plant boiler according to the invention comprises a silencer according to the invention in its flue gas duct.

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Fig. 6a is a side view of a part of the flue gas duct of a combustion boiler. The figure illustrates a water preheating area 200, a Savusola 300 and a supply air preheating area 250. Said areas lie between the first side walls 206, 306 and 256 and the second side walls 208, 308 and 258. The preheating area 200 for the water 20 comprises heat exchanger tubes 212. The heat exchanger tubes used for preheating the water may have a diameter of about 40 mm and the distance between the tubes may be about 70 mm (from center to center). In addition, the combustion air preheating area comprises heat exchanger tubes 262. The heat exchanger tubes 25 2 62 used for preheating the combustion air may be, for example, 50 mm in diameter. For example, the distance between the heat exchanger tubes 262 may be 75 mm. In Fig. 6a, the muffler 300 is provided with a silencer according to Fig. 3b. Said view of the silencer plates shows the wall 340 and the silencer plates 320c in the vicinity of the flue gas duct ^ and the silencer plates 320b in the vicinity of the wall 340.

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6a, the noise level of the combustion boiler of Fig. 6a is further reduced by providing vibration dampers 600 in the flue gas duct. The dampers 600 are substantially parallel to the direction of flow of the flue gases. The burner boiler 35 may comprise an oscillation baffle 600 in the water preheating region 200. The burner boiler may further comprise, or alternatively, a vibration baffle 600 in the air preheating region 258. The oscillator baffle 600 is arranged between the heat exchanger tubes perpendicular to the flue gas flow direction. Thus, the resonance 40 in the heat exchanger region of the flue gas duct may be reduced. In Fig. 6a, the heat exchanger tubes are substantially perpendicular to the flue gas flow direction. Some solutions 13 utilize heat exchanger tubes that are substantially parallel to the flow direction of the flue gases. In addition, the anti-vibration plates are substantially parallel to the heat exchanger tubes. The distance between the heat exchanger tubes is typically less than the thickness of the silencer plate 320. As described above, the distance between the heat exchanger tubes may be, for example, in the order of a few centimeters, whereby a sound absorbing silencer plate can be mounted between the heat exchanger tubes. The vibration damping plate 600 may be a metal plate which may, for example, be designed to reflect sound and thus change the resonant frequency. The thickness of the anti-vibration plate may be between 1 and 15 mm, and for example about 5 mm. In addition, the vibration damping plates may be located at various distances from each other and / or the wall of the flue gas duct, whereby a plurality of characteristic resonance frequencies are formed in the flue gas duct corresponding to the spacing of the plates or wall or depth or depth of the flue gas duct. Vibration suppression plates 600 may also be used between heat exchanger tubes 132 of evaporator 130.

The silencer may be located in the flue gas duct relative to the direction of flow of the flue gases before the vibration damping plates 600, the silencer may be located after the vibration damping plates, or the silencer may be located in this direction between the two vibration damping plates. The anti-vibration plates may be substantially perpendicular to the wall 340.

In one experiment, the noise level of a combustion boiler was measured when only vibration damping plates 600 were provided in the flue gas duct and an additional muffler was provided in the smoke duct 300 of the flue gas duct. The sound attenuator was found to reduce the noise level at 10 to 15 dB at some frequencies compared to the situation where sound attenuation was only achieved with the anti-vibration plates 600. The attenuator provided attenuation at low frequencies, in particular the third resonant frequency. In the experiments, the embodiment of Fig. 3b was used and the thickness of the silencer plates used was 300

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Figure 6b shows a sectional view of the flue gas duct of the combustion boiler according to Figure 6a in a second side view. Particularly for the smoke salt 300, the silencer 35 exhibits a wall 340 as well as substantially straight silencer plates against it. The silencer plates of the wall 340 could also be arranged in the frame 500. The silencer is supported in place, although the g and lower support structures 510 and 520 are not shown in Figures 6a-6c.

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Figure 6c shows a section of a flue gas duct of a combustion boiler. The image is substantially similar to Figure 6a, but the flue gas muffler is rotated in a direction perpendicular to the flue gas flow of 90 degrees, and the length of the wall 340 and the portions of the perpendicular sections 320b and 320c respectively. The perpendicular parts may also comprise more than one silencer plate. For example, rotating the image 5 3c 90 degrees clockwise may substantially result in the silencer solution of Figure 6c.

Further, it has been found that the sound-absorbing muffler plates 320 perform particularly well if they are located in the flue gas duct relative to the downstream direction of the flue gases after the heat exchanger tubes. Such heat exchanger tubes may be, for example, heat exchanger tubes 132 of the evaporator 130, heat exchanger tubes 212 of the water preheater, or heat exchanger tubes 262 of the combustion air preheater. 212, 262.

It is possible that the flue gas flow heat exchanger tubes (132, 212, 262) cause turbulence in the flue gas flow. Vortex 20, in turn, can make time for noise. It may be that the muffler works well just after the heat exchanger tubes due to the described sound generation mechanism. In addition, space must be provided for the silencer and its silencer plates 320 in the flue gas duct. In some applications, the flue gas duct has space for the silencer just in the smoke salt 300 between the water preheat zone 25 and the air preheat zone.

Further, the positioning of the silencer plates after the heat exchanger tubes has the advantage that the temperature of the flue gases after the heat exchanger tubes is lower than before the heat exchanger tubes, whereby the silencer is not exposed to δ 30 as hot environment as when placed before the heat exchanger tubes. Pre- C \ l

For example, the heat exchanger plates may be arranged to withstand about 400 ° C

9 temperatures at which the flue gases should be cooled before the muffler.

o Cooling is preferably done by combustion boiler heat exchanger tubes, x which recover heat. Such heat resistance can be achieved by, for example, using 326 carbon blades as the surface plate of the silencer plate 320. Certain materials, such as ceramics, may withstand higher heat conditions. In one embodiment, the face plate 326 comprises carbon steel.

Preferably, at least one silencer plate 320 is located in the flue duct 40 immediately downstream of either the water preheater heat exchanger tube 212 15 of the evaporator heat exchanger tube 132 or the air preheater heat exchanger tube 262. This may leave a distance d between the sound attenuator plate 320 and the heat exchanger tube. Figure 7 is a side elevational view of a flue gas duct of a combustion boiler. In the embodiment of Fig. 7, the flue gas duct of the combustion boiler has a water preheating area 200, an air preheating area 250, and a Savusola 300 in the flow direction of the flue gases, respectively. 7, the combustion boiler of Figure 7 further comprises vibration damping plates 600. In other embodiments of the invention, there is no vibration damping plate 600. In the embodiment of Figure 7, the distance d is between the damping plate 320 and the heat exchanger tube 262. The distance d is measured from the heat exchanger tube 262 substantially in the direction of flow of the flue gases towards the muffler plate 320. It is clear that the other heat exchanger tubes may be greater from distance. In said directions, the distance d is positive, i.e., the distance does not refer to the distance between the muffler plate and, possibly, the heat exchanger tube following it in the flue gas flow direction. The distance d is preferably small, whereby a large amount of sound-absorbing material, i.e. a large silencer plate 320, can be provided in the empty space of the flue gas duct. Such resonance can be prevented if, for example, the distance d is less than the channel width W or less than the channel depth L, then the distance d is less than greater than these dimensions. Resonance can be prevented if, for example, the distance d is less than the channel width 1/1 / and less than the channel depth L, whereby the distance d is smaller than these dimensions. In addition, for example, a channel of circular or δ 30 square cross-section may have the same width and depth. For example

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Therefore, with said flue gas channel size, the distance d may be less than 8 m or less than 9 3.5 m. The distance may also be smaller, for example less than 2 m. Preferably, the distance d is less than 1m, and most preferably about 0.5m. The distance d may also be less than x, but in this case the attachment of the plates to the structure may be fish. In other embodiments, the distance d may remain between the water preheater heat exchanger tube 212 and the muffler plate 320 or the evaporator to heat exchanger tube 132 and the muffler plate 320, depending on which heat exchanger plate the muffler plate 320 is placed.

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40 If the muffler is close to the heat exchanger tubes, simpler muffler solutions can also achieve adequate noise suppression. Here, for example, a simple silencer may consist of a sound absorbing silencer plate 320. Alternatively, the silencer may comprise a sound absorbing silencer plate 320.

8a shows a silencer comprising silencer plates 320. Silencer plates 320 form a wall 340. Silencer plates 320 are substantially parallel to each other. The wall 340 is arranged to cut off the resonating space in the flue gas channel width direction corresponding to the width \ N. In one embodiment, the wall 340 is shorter than the depth direction (corresponding to the depth L) of the flue gas 10, wherein the wall 340 is arranged to narrow the width of the resonating region.

Figure 8b shows a silencer comprising a plurality of parallel muffler plates 320. The parallel muffler plates form parallel walls 340. The parallel walls 340 are spaced apart in a direction perpendicular to the flow direction of the flue gases. The walls may be parallel to one of the walls of the flue gas duct, for example, to the front wall 302 or side wall 306. The walls 340 may also be angled with respect to the front wall 302 or the side wall 306.

The silencer shown in Figure 8b does not have a single service passageway through which all walls 302, 304, 306 and 308 of the flue gas duct can be accessed. In this case, the burner boiler may comprise a creep-son 700 to maintain the silencer (Figure 7). There is a creep space 710 between the creep plane 700 and the silencer plate 320. With such creep space 710, it is also possible to maintain the silencer of Figure 8b. In this case, the height of the creep space 710, i.e. the distance between the creep plane 700 and the silencer plate 320, may be such that from the creep space the service person can crawl from the service corridor δ 30 330a to another service corridor 330b. The height of the crawl space may be, for example,

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^ 50 cm, 60 cm or 70 cm. Preferably, the creep space is low, whereby the height of the muffler plate may be high. For example, the service person may move to creep level 700 and service the first portion of the muffler x along the service passage 330a. Through crawl space 710, the service person can move to “35 next service corridor 330b and further to the next service corridor 330c. Thus, with the creep plane 700, the muffler plates to 320 and the flue gas duct walls 302, 304, 306 and 308 can be maintained.

δ 00 The silencer plates protected with a bottom or top cover 328 (Figures 4a and 40 4b) can be used in the silencer. The silencer plates can be mounted in a frame 500 (Figures 5a and 5b). The frame may be secured in place by support structures 510 or 520. In some embodiments, support structure 510 or 520 may be attached to air or water preheater support structure or evaporator 130 support structure. Further, the silencer may comprise a service passageway that accesses the flue gas duct walls 302, 304, 306 5 and 308 of the combustion boiler and the silencer plates 320.

The silencer shown may be used in combustion boilers, such as power plant boilers. One example of a power plant boiler is a fluidized bed boiler. The solution shown may be located in a substantially vertical or substantially horizontal flue gas duct, or the flue gas duct may be at another angle.

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Claims (11)

1. Silencers for a flue gas duct of a combustion boiler, which - silencers comprise at least one first (320, 320a) and a second (320, 320b) piano silencer disc substantially in the direction of flue gas flow, which silencer discs (320, 320a, 320b) , characterized in that - the silencer is arranged to be placed in the flue gas duct having a substantially rectangular shape in a direction of flow of the flue gas perpendicular to the perpendicular cross-sectional plane, - the first silencer disc (320a) is arranged to be disposed in the flue gas duct wall 30 306, 308) and - the second silencer disc (320b) is substantially perpendicular to said first silencer disc (320a), the width of the flue gas resonant region narrowing in two directions perpendicular to the direction of flow of the flue gases. Silencer according to claim 1, characterized in that the silencer 20 comprises - a wall (340) comprising said first silencer disc (320a) and said wall (340) arranged to be positioned substantially in the middle of the flue gas duct, - said second silencer disc ( 320b) which is substantially perpendicular to said wall (340), and - a third silencer disc (320c) substantially perpendicular to said wall (340) and whose distance from the wall (340) is greater than that of the second silencer disc (320b) distance from the wall (340). O Silencer according to claim 1 or 2, characterized in that when the CL silencer's silencer discs (320) are placed in the flue gas duct, they cut a resonating area perpendicular to the direction of flow of the LO flue gas duct gas, S - in the flue gas duct duct 35. or - in the width direction of the flue gas duct and in the deep direction of the flue gas duct, Silencer according to any of claims 1-3, characterized in that the silencer discs (320) define the silencer discs in a substantially perpendicular panel of a service corridor (330) for performing the silencer, silencer disc (320) or the flue gas duct. 5 Silencer according to claim 4, characterized by the service corridor having access to the silencer's sides and to the silencer plates (320). Silencer according to any of claims 1-5, characterized in that the silencer disc (320) comprises - a sound-absorbing core (322) comprising sound-absorbing material, for example soft mineral wool and - on its surface a surface plate (326) to protect the silencer disc. inner parts, which surface includes heels for transmitting sound. 15 Silencer according to any of claims 1-6, characterized in that at least one silencer disc (320) is placed within a frame (500) to protect the silencer disc (320) against a soot device. 20 8. A combustion boiler, characterized in that it comprises - a flue gas duct having a substantially rectangular shape in a cross-sectional plane perpendicular to the direction of the flue gas and - in the flue gas duct a silencer according to any of the preceding claims 1-7. 25 ? Combustion boiler according to claim 8, characterized in that the flue gas duct comprises CD 0 and two parallel side walls (306, 308) and a front wall (302) which is substantially perpendicular to the side wall (306, 308) 30 and a rear wall. (304), wherein the combustion boiler silencer CL silencer discs (320) are arranged such that - between the parallel side walls of the flue gas channel there is no perpendicular visual LO contact and ™ - between the flue gas parallel front wall (302) and rear wall (304) is no perpendicular Combustion boiler according to claim 8 or 9, characterized in that - the combustion boiler comprises heat exchange pipes (132, 212, 262) in said flue gas duct and - said silencers are arranged in the flue gas duct in the flow direction of the flue gases 5 after said heating pipe 21 heat exchange pipes (132, 212) or • between said some heat exchange pipes (132, 212) and some other said heat exchange pipes (212, 262). 10 The combustion boiler according to any one of claims 8-10, characterized in that - the combustion boiler comprises heat exchanger pipes (132, 212, 262) in said flue gas duct and the combustion boiler comprises a barrier disc (600) against vibrations, which is a pane disk essentially in the flue gas stream and which anti-vibration barrier disc (600) is in a perpendicular direction to the flue gas flow direction between two heat exchange tubes (132, 212, 262), to reduce resonance in the flue gas heat exchange region. 20 't δ c \ j CD O o X CC CL CVJ m m δ c \ j