Boiler
1. A boiler, characterized in that it comprises:
the device comprises a shell (110), wherein the shell (110) is provided with a water filling port (111) and an exhaust port (112), and the water filling port (111) and the exhaust port (112) are communicated with an inner cavity of the shell (110);
the hearth (120) is connected with the shell (110), at least part of the hearth (120) is located in the shell (110), the top of the hearth (120) is provided with an air outlet (121), the bottom of the hearth (120) is provided with an ash outlet (122), and the hearth (120) is provided with an air inlet pipe (123);
the first sound wave ash remover (130), the first sound wave ash remover (130) is arranged in the hearth (120), the first sound wave ash remover (130) is positioned outside the shell (110), one end of the first sound wave ash remover (130) is communicated with the inner cavity of the hearth (120), and the first sound wave ash remover (130) is arranged close to the air outlet (121);
the second sound wave ash removal device (140), the second sound wave ash removal device (140) is arranged in the hearth (120), a part of the second sound wave ash removal device (140) is located in the shell (110), one end of the second sound wave ash removal device (140) is communicated with the inner cavity of the hearth (120), and the other end of the second sound wave ash removal device extends out of the shell (110).
2. The boiler according to claim 1, wherein an obstruction plate (150) is provided in the furnace (120), the obstruction plate (150) being provided with a plurality of first through holes, the obstruction plate (150) being disposed adjacent to the air outlet (121).
3. The boiler according to claim 2, wherein the direction in which the ash outlet (122) extends toward the air outlet (121) is a first direction, the number of the blocking plates (150) is at least two, each of the blocking plates (150) is arranged at intervals along the first direction, and the cross-sectional dimension of the first through-hole of each of the blocking plates (150) is gradually reduced in the first direction.
4. The boiler according to claim 2, wherein a sub-screen plate (160) is arranged in the furnace (120), the sub-screen plate (160) is provided with a plurality of second through holes, and the sub-screen plate (160) is positioned on a side of the obstruction plate (150) facing away from the air outlet (121).
5. The boiler according to claim 4, wherein the direction in which the ash outlet (122) extends toward the air outlet (121) is a first direction, the number of the sub-screen plates (160) is at least two, the sub-screen plates (160) are arranged at intervals along the first direction, and the cross-sectional size of the second through-hole of each sub-screen plate (160) is gradually increased in the first direction.
6. The boiler according to claim 4, wherein the direction in which the ash outlet (122) extends towards the air outlet (121) is a first direction, the boiler further comprising a bracket (170), the bracket (170) being slidably disposed in the furnace (120) along the first direction, the sub-screen deck (160) being disposed on the bracket (170).
7. The boiler according to claim 6, further comprising a driving mechanism connected to the bracket (170), the driving mechanism driving the bracket (170) to move.
8. The boiler according to claim 7, wherein the driving mechanism comprises a driving source, a sliding plate (210) and a roller (220), the driving source is disposed outside the housing (110), the driving source is connected to the sliding plate (210), the sliding plate (210) is provided with an arc-shaped driving surface (211), the roller (220) is rotatably disposed on the bracket (170), the roller (220) is engaged with the arc-shaped driving surface (211), the driving source drives the sliding plate (210) to move along the second direction, and the sliding plate (210) drives the bracket (170) to move through the roller (220);
wherein the second direction is perpendicular to the first direction.
9. The boiler according to claim 8, wherein the driving mechanism further comprises a gear (230) and a rack (240), the driving source is connected to the gear (230), the rack (240) is slidably disposed on the furnace (120) along the second direction, the rack (240) is engaged with the gear (230), and the rack (240) is connected to the sliding plate (210), and the driving source drives the rack (240) to move through the gear (230).
10. The boiler according to claim 1, wherein at least two of the first sonic ash cleaner (130) and the second sonic ash cleaner (140) are provided in the peripheral direction of the furnace (120);
the direction of the ash outlet (122) extending to the air outlet (121) is a first direction, and at least two first sound wave ash cleaners (130) and at least two second sound wave ash cleaners (140) are arranged in the first direction.
Background
A thermal power plant is a plant for producing electric energy using combustible (e.g. coal) as fuel, and its basic production processes are: when the fuel is burnt, water is heated to generate steam, chemical energy of the fuel is converted into heat energy, the steam pressure pushes a steam turbine to rotate, the heat energy is converted into mechanical energy, and then the steam turbine drives a generator to rotate, so that the mechanical energy is converted into electric energy.
The boiler is one of three big host computers in the thermal power plant, has important influence to the efficiency and the reliability of thermal power plant electricity generation, and current boiler during operation can produce more flue gas after the inside fuel burning of furnace, and wherein mix more cigarette ash, lead to cigarette ash to discharge in a large number, cause very big vexation to the post treatment.
Disclosure of Invention
The purpose of the embodiment of the application is to provide a boiler, can solve the problem that more cigarette ash is mixed in the flue gas that the boiler produced.
In order to solve the technical problem, the present application is implemented as follows:
an embodiment of the present application provides a boiler, includes:
the gas exhaust port is communicated with the inner cavity of the shell;
the hearth is connected with the shell, at least part of the hearth is positioned in the shell, the top of the hearth is provided with an air outlet, the bottom of the hearth is provided with an ash outlet, and the hearth is provided with an air inlet pipe;
the first sound wave ash remover is arranged in the hearth and is positioned outside the shell, one end of the first sound wave ash remover is communicated with the inner cavity of the hearth, and the first sound wave ash remover is arranged close to the air outlet;
and one end of the second sound wave ash removal device is communicated with the inner cavity of the hearth, and the other end of the second sound wave ash removal device extends out of the shell.
In the embodiment of this application, be provided with first sound wave deashing ware and second sound wave deashing ware on the furnace, first sound wave deashing ware and second sound wave deashing ware can send the sound wave to the cigarette ash in the flue gas in the clearance furnace, and then reduce the cigarette ash content in the exhaust flue gas, so that post processing.
Drawings
FIG. 1 is a schematic structural diagram of a boiler disclosed in an embodiment of the present application;
FIG. 2 is a sectional view of a boiler disclosed in an embodiment of the present application;
FIG. 3 is an enlarged view of a portion of FIG. 2 at A;
FIG. 4 is a partial cross-sectional view of a boiler disclosed in an embodiment of the present application.
Description of reference numerals:
110-shell, 111-water filling port, 112-air outlet, 120-hearth, 121-air outlet, 122-ash outlet, 123-air inlet pipe, 124-body, 125-upper cover, 130-first sound wave ash remover, 140-second sound wave ash remover, 150-baffle plate, 160-screen separating plate, 170-bracket, 180-supporting leg, 210-sliding plate, 211-arc driving surface, 220-roller, 230-gear and 240-rack.
Detailed Description
The technical solutions in the embodiments of the present application will be described clearly and completely with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some, but not all, embodiments of the present application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
The terms first, second and the like in the description and in the claims of the present application are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application are capable of operation in sequences other than those illustrated or described herein. In addition, "and/or" in the specification and claims means at least one of connected objects, a character "/" generally means that a preceding and succeeding related objects are in an "or" relationship.
The boiler provided by the embodiment of the present application is described in detail by specific embodiments and application scenarios thereof with reference to the accompanying drawings.
Referring to fig. 1 to 4, an embodiment of the present application discloses a boiler, which includes a housing 110, a furnace 120, a first sonic ash remover 130, a second sonic ash remover 140, and legs 180.
The outer shell 110 may serve as a base component of the boiler, thereby providing a mounting base for other components of the boiler. The legs 180 may be disposed at the bottom of the outer shell 110 such that the outer shell 110 is located away from the ground to facilitate the placement of the components contained in the boiler while facilitating heat dissipation. The housing 110 is provided with a water filling opening 111 and an exhaust opening 112, the water filling opening 111 and the exhaust opening 112 are both communicated with the inner cavity of the housing 110, and the water filling opening 111 and the exhaust opening 112 can be both arranged at the top of the housing 110. Furnace 120 can provide the combustion place for fuel, furnace 120 links to each other with shell 110, and furnace 120 is located shell 110 at least partially, therefore can form accommodation space between furnace 120 and the shell 110, the top of furnace 120 is equipped with gas outlet 121, the bottom of furnace 120 is equipped with ash hole 122, and furnace 120 is equipped with intake pipe 123, the one end of this intake pipe 123 and furnace 120 intercommunication, the other end can pass and stretch out shell 110 behind shell 110, intake pipe 123 can set up to one, also can set up to a plurality ofly. The direction in which the ash outlet 122 extends toward the air outlet 121 is a first direction, and optionally, the axes of the ash outlet 122 and the air outlet 121 are collinear.
When the boiler works, water can be added into the inner cavity of the shell 110 through the water adding port 111, the added water is positioned in the accommodating space enclosed by the shell 110 and the hearth 120, meanwhile, air can be introduced into the inner cavity of the hearth 120 through the air inlet pipe 123, so that fuel in the hearth 120 is combusted, the water in the shell 110 is further heated, water vapor is generated, and the generated water vapor is discharged through the exhaust port 112. Gas generated by the combustion of the fuel is discharged from the gas outlet 121, and soot generated is discharged from the soot outlet 122.
The first sonic ash remover 130 is disposed on the furnace 120, the first sonic ash remover 130 is disposed outside the housing 110, one end of the first sonic ash remover 130 is communicated with the inner cavity of the furnace 120, the first sonic ash remover 130 is disposed adjacent to the air outlet 121, that is, the first sonic ash remover 130 can be mounted on the top of the furnace 120. The second sonic ash cleaner 140 is disposed in the furnace 120, a part of the second sonic ash cleaner 140 is disposed in the casing 110, one end of the second sonic ash cleaner 140 is communicated with the inner cavity of the furnace 120, and the other end extends out of the casing 110. Optionally, a second sonic ash cleaner 140 is positioned between the air outlet 121 and the ash outlet 122 of the furnace 120. The first and second sonic ash removers 130 and 140 can emit sonic waves, which act on the flue gas in the furnace 120 to vibrate the flue gas, so as to separate the soot in the flue gas, and the separated soot is discharged from the soot outlet 122 under the action of gravity. Therefore, the first acoustic deashing device 130 and the second acoustic deashing device 140 in the embodiment of the present application can clean the soot in the flue gas in the furnace 120, thereby reducing the soot content in the discharged flue gas for post-treatment.
In a further embodiment, a blocking plate 150 may be disposed in the furnace 120, the blocking plate 150 is provided with a plurality of first through holes, the first through holes may be arranged at intervals, and the first through holes may communicate with spaces on two sides of the blocking plate 150, so that the flue gas may pass through the blocking plate 150 to flow to the gas outlet 121, and finally be discharged from the gas outlet 121. The blocking plate 150 is disposed adjacent to the air outlet 121, i.e., the blocking plate 150 is disposed at the top of the furnace 120. The baffle 150 can apply resistance to the flue gas, so that the flow speed of the flue gas is slowed down, and the flue gas stays at the gas outlet 121 for a longer time, so as to prolong the acting time of the first acoustic wave ash remover 130 and the flue gas, so that the first acoustic wave ash remover 130 can more fully treat the soot in the flue gas, and further improve the soot cleaning effect.
The number of the blocking plates 150 may be one or at least two. In an alternative embodiment, the number of the baffle plates 150 is at least two, each baffle plate 150 is arranged at intervals along the first direction, and the cross-sectional size of the first through holes of each baffle plate 150 is gradually reduced in the first direction, at this time, the density of the first through holes of each baffle plate 150 is gradually increased in the first direction, so that the flow speed of the flue gas is slower as the first through holes are closer to the air outlet 121, so that the first acoustic wave ash remover 130 can more fully act on the soot in the flue gas, thereby further improving the ash removing effect.
Optionally, the number of the blocking plates 150 may be four, so as to fully utilize the top space of the hearth 120, and further generate a better blocking effect on the flue gas, and meanwhile, the flue gas may not generate too much resistance, so as to ensure that the flue gas can be smoothly discharged. In addition, the hearth 120 may include a body 124 and an upper cover 125, which may be welded, screwed, clamped, etc., wherein the body 124 is at least partially disposed inside the casing 110, the ash outlet 122 and the second sonic ash remover 140 are disposed on the body 124, the upper cover 125 is disposed outside the casing 110, and the air outlet 121 and the first sonic ash remover 130 are disposed on the upper cover 125. Such a configuration facilitates subsequent maintenance of the furnace 120.
In an alternative embodiment, the dividing screen plate 160 is disposed in the furnace 120, the dividing screen plate 160 is provided with a plurality of second through holes, the second through holes may be arranged at intervals, and the second through holes may communicate with spaces on both sides of the dividing screen plate 160, so that the soot may flow through the dividing screen plate 160 to the soot outlet 122, and finally be discharged from the soot outlet 122. The sub-sieve plate 160 is located at a side of the blocking plate 150 facing away from the air outlet 121, that is, the sub-sieve plate 160 is located below the blocking plate 150, and the sub-sieve plate 160 can provide a supporting force for the fuel, so that the fuel can be maintained at a predetermined position of the furnace 120, and the air introduced into the furnace 120 can be more sufficiently contacted with the fuel, so that the fuel can be more sufficiently combusted.
The number of the sub-sieve plates 160 may be one or at least two. In an alternative embodiment, the number of the sub-sieve plates 160 is at least two, the sub-sieve plates 160 are arranged at intervals along the aforementioned first direction, and in the first direction, the cross-sectional size of the second through holes of each sub-sieve plate 160 is gradually increased, and at this time, in the first direction, the density of the second through holes of each sub-sieve plate 160 is gradually decreased. As the burning time is increased, the particle size of the fuel in the furnace 120 is decreased gradually, so that the fuel can drop on different sub-sieve plates 160 step by step, the contact time between the fuel and the air is further prolonged, and the fuel can be burned more sufficiently.
Optionally, the number of the sub-sieve plates 160 may be set to three, so as to fully utilize the inner cavity space of the hearth 120, thereby generating a better sieving effect on fuel, and meanwhile, not generating too much resistance on the soot, so as to ensure that the soot can be smoothly discharged.
In order to improve the smoothness of ash discharge, the boiler may further include a bracket 170, the bracket 170 is slidably disposed in the furnace 120 along the first direction, and the sub-screen 160 is disposed on the bracket 170. Alternatively, the bracket 170 may be driven to move relative to the furnace 120 by a manual operation manner, and the bracket 170 may also be driven to move relative to the furnace 120 by an electric manner, which is not limited in this embodiment of the application. When the bracket 170 moves relative to the furnace 120, the separation screen plate 160 moves along with the movement, thereby facilitating the fuel staying on the separation screen plate 160 to fall to the next separation screen plate 160, and simultaneously facilitating the soot to separate from the separation screen plate 160, thereby preventing the blockage in the furnace 120.
Further, in order to improve the degree of automation of the boiler, the boiler further includes a driving mechanism connected to the supporter 170, and the driving mechanism drives the supporter 170 to move. So set up, need not manual operation support 170 remove to promote the degree of automation of boiler, so that support 170 can remove more accurately, and can promote the security of boiler.
The driving mechanism can adopt components which can output linear driving force, such as a telescopic cylinder and the like, and the components can be directly connected with the bracket 170, but the driving mechanism is integrally installed in the hearth 120 due to the arrangement, the temperature in the hearth 120 is higher, a large amount of soot exists, and the driving mechanism is not favorable for reliable work. To this end, in other embodiments, the driving mechanism may include a driving source, a sliding plate 210 and a roller 220, the driving source is disposed outside the housing 110, the driving source is connected to the sliding plate 210, the sliding plate 210 may be located inside the furnace 120 and provided with an arc-shaped driving surface 211, the roller 220 is rotatably disposed on the bracket 170, the roller 220 is engaged with the arc-shaped driving surface 211, the driving source drives the sliding plate 210 to move in the second direction, and the sliding plate 210 drives the bracket 170 to move via the roller 220. It should be noted that the second direction is perpendicular to the first direction. The driving source may drive the sliding plate 210 to move, and the sliding plate 210 may drive the roller 220 to move in the first direction via the arc-shaped driving surface 211, thereby moving the bracket 170, and at the same time, the roller 220 rolls along the arc-shaped driving surface 211. With the structure, the driving source is positioned outside the hearth 120, so that the driving source is not influenced by the environment in the hearth 120 and can work more reliably. And, the roller 220 is in rolling fit with the arc-shaped driving surface 211, so that the abrasion caused by the rolling fit is small, and the service life of the driving mechanism is prolonged.
The driving source may be directly connected to the sliding plate 210, and the driving force output by the driving source is a linear driving force at this time, in another embodiment, the driving mechanism further includes a gear 230 and a rack 240, the driving source is connected to the gear 230, the rack 240 is slidably disposed in the hearth 120 along the second direction, the rack 240 is engaged with the gear 230, and the rack 240 is connected to the sliding plate 210, and the driving source drives the rack 240 to move through the gear 230. In this embodiment, the drive source may output a rotational drive force, and alternatively, the drive source may be a motor, which requires a small movement space, thereby facilitating the installation of the drive mechanism. In addition, the manner of transmitting the driving force by the manner of engaging the gear 230 with the rack 240 has advantages of high transmission accuracy, high transmission efficiency, long working life, and the like.
The first and second sonic ash removers 130 and 140 may be provided with only one, but in order to improve the ash removal effect, at least two first and second sonic ash removers 130 and 140 are provided in the peripheral direction of the furnace 120. The first and second sonic ash removers 130 and 140 arranged along the peripheral direction of the furnace 120 can act on the flue gas at different areas in the furnace 120, thereby improving the ash removal effect. Further, in the first direction described above, at least two of the first sonic ash collector 130 and the second sonic ash collector 140 are provided. Likewise, the first acoustic ash remover 130 and the second acoustic ash remover 140 arranged along the first direction can act on the flue gas at different areas in the furnace 120, thereby improving the ash removal effect.
While the present embodiments have been described with reference to the accompanying drawings, it is to be understood that the invention is not limited to the precise embodiments described above, which are meant to be illustrative and not restrictive, and that various changes may be made therein by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.