KR102107223B1 - Fine dust reduction system with wind power generator - Google Patents

Abstract

The present invention configures devices capable of reducing fine dust in a process system in which an incinerator is installed to discharge clean air, and furthermore, fine dust having a wind power generator capable of generating wind power using the clean air emitted The aim is to provide an abatement system.
To this end, it is connected to the incinerator, one or more water spray unit for spraying water to collect the fine dust generated by the operation of the incinerator; At least one collecting unit connected to the water injection unit to receive dust-collected water from the water injection unit and discharge dust-filtered water to the outside; An air discharge part connected to the water spray part to form a longitudinal direction upward, and exhausting air passing through the water spray part to the outside; It is possible to provide a fine dust reduction system having a wind power generator that is provided at the top of the air discharge part and operates using wind and external wind discharged, and a wind power generator that includes a water supply part that supplies water to the water injection part. .
Through this, the fine dust reduction system having a wind power generator according to an embodiment of the present invention has an advantage of effectively collecting fine dust of a process system in which an incinerator is installed by forming at least two water injection systems, Equipped with one or more water collecting sections, it has the advantage of effectively filtering out fine dust from the collection of fine dust and sending only clean water out.It is equipped with a wind power generator at the end of the air exhaust section of the process system, so that fine dust is collected and discharged. By making it possible to generate electricity through, there is an advantage of using energy more effectively.

Description

Fine dust reduction system with wind power generator

The present invention relates to a fine dust reduction system, in particular, to a fine dust reduction system that can also be carried out with wind power generator having a wind power generator.

In general, fine dust is a suspended substance in the atmosphere having various complex components, and particles smaller than 10 micrometers in diameter and larger than 2.5 micrometers are called fine dust, and particles less than 2.5 micrometers are called ultrafine dust. The fine dust is small in size and can enter human lungs and blood, and due to its characteristics mainly composed of carbon, organic hydrocarbon, nitrate, sulfate, and harmful metal components, exposure of fine dust can cause respiratory and cardiovascular diseases. It can be reported that it can deteriorate health and greatly increase mortality.

In the case of such fine dust, it is mainly generated when burning of a vehicle or incineration of something in an industrial complex or agro-industrial or waste facility. In particular, in the case of private power generation facilities equipped with incinerators, manufacturing combustion facilities, concentrated water industry facilities, and waste incineration facilities, PM _2.5 emissions in turn are approximately 635 (ton/yr) and 493 (ton/yr), respectively. ), about 418 (ton/yr), about 221 (ton/yr), and many of them are in the top 20 of PM _2.5 emissions, indicating that the rate of fine dust generation is considerable.

Research report on the study of health impact assessment and management policy of ultra fine dust (PM2.5) 2012-03, Sung-Yong Gong et al.

In order to solve the above problems, the present invention configures devices capable of reducing fine dust in a process system in which an incinerator is installed to discharge clean air, and furthermore, wind power can be generated by using clean air that is discharged. It is to provide a fine dust reduction system having a wind power generator.

In order to solve the problems as described above, the present invention is connected to an incinerator, and one or more water spraying units for spraying water to collect fine dust generated according to the action of the incinerator; At least one collecting unit connected to the water injection unit to receive dust-collected water from the water injection unit and discharge dust-filtered water to the outside; An air discharge part connected to the water spray part to form a longitudinal direction upward, and exhausting air passing through the water spray part to the outside; It is possible to provide a fine dust reduction system having a wind power generator that is provided at the top of the air discharge part and operates using wind and external wind discharged, and a wind power generator that includes a water supply part that supplies water to the water injection part. .

Here, the water injection unit, the water injection unit housing forming a space therein; One or more supply pipes coupled to the inner surface of the water injection unit housing and connected to the water supply unit to receive water; It is connected to be supported by the supply pipe and includes a first water injection device for spraying water into the housing of the water injection unit and a discharge pipe provided at the bottom of the water injection unit housing and connected to the water collection unit to transmit fine dust collection. , The first water spray device may include a flow pipe through which water flows by forming a length in a spiral shape and a plurality of spray nozzles formed in the flow pipe.

In addition, the air discharge unit is provided with a second water injection device at the bottom to collect fine dust that has passed through the water injection unit, and the bottom of the air discharge unit is the water collecting unit to discharge water from the second water injection device. It can be connected with.

In addition, the wind turbine, the support portion coupled to the outside of the air discharge portion; A wing portion formed above the support portion to generate rotational force with air discharged from the air discharge portion; It is formed above the wing portion, and is exposed to the outside to accommodate external air, and includes a support portion for increasing the rotational force and a driving portion provided at the top and developed by the rotational force transmitted from the wing portion and the support portion. The wing portion may be connected by one rotating shaft.

In addition, the wing portion, attached to the top and bottom of the wing portion, while passing through the wind of the air discharge portion at the same time to support the rotating shaft and two rotating shaft support; A helical inner wing formed along the outer periphery of the rotating shaft between the two rotating shaft supports and a wing housing formed between the two rotating shaft supports to surround the outside of the inner driving blade may be included.

In addition, the rotating shaft is provided with a conical industrial diamond at the lower end of the wing portion, and can be rotated while minimizing friction by making linear contact with the lower shaft rotating shaft support.

In addition, the support portion includes at least three drive portion support bars supporting the drive portion, and an external mechanism wing formed in a screw shape and formed along the length of the rotation shaft between the drive portion and the wing portion, wherein the rotation shaft is provided on the external mechanism wing. By this, the rotational force can be increased by the external wind.

In addition, the driving unit, the driving unit housing forming a space therein; An internal gear formed along one inner circumferential surface of the driving unit housing; A rotating plate coupled to the rotating shaft and connected to the internal gear; A transmission gear meshing with the internal gear; A generator gear meshing with the transmission gear; A generator connected to the generator gear to generate electricity; The generator may be connected to the generator to store electricity of the generator, and may include a generator housing incorporating the generator and the battery.

In addition, the water supply unit may be connected to the water injection unit, including a water tank and a water pump.

On the other hand, the fine dust reduction system provided with the wind power generator, may be provided with an incineration ash filter at the connection between the incinerator and the water spray.

In addition, the fine dust reduction system having the wind power generator further includes a water supply control unit including a concentration sensor and a control unit, and the concentration sensor is installed at the lower portion of the water collecting unit to interlock with the control unit, and the concentration of fine dust. Measure and transmit to the control unit, the control unit may adjust the water supply amount of the water supply unit according to the concentration of the fine dust measured from the concentration sensor.

In addition, the fine dust reduction system equipped with the wind power generator further includes an air induction unit installed on the air exhaust unit, and the air induction unit includes a rotating fan and a motor to induce air to be rapidly discharged. .

The fine dust reduction system having a wind power generator according to an embodiment of the present invention has an advantage of effectively collecting fine dust of a process system in which an incinerator is installed by forming at least two water injection systems.

In addition, the fine dust reduction system having a wind power generator according to an embodiment of the present invention has an advantage of having at least one water collecting part to effectively filter fine dust of the fine dust collecting water and to send out only clean water.

In addition, the fine dust reduction system having a wind power generator according to an embodiment of the present invention, by providing a wind power generator at the end of the air exhaust portion of the process system to allow the fine dust to be collected and discharged through clean air to generate power, It has the advantage of using energy more effectively.

1 is a schematic diagram of a fine dust reduction system having a wind power generator according to an embodiment of the present invention.
2 is a view illustrating the internal configuration of a water spray unit of a fine dust reduction system having a wind power generator according to an embodiment of the present invention.
3 is a perspective view illustrating an inside of a wind power generator of a fine dust reduction system having a wind power generator according to an embodiment of the present invention.
4 is a front view showing the inside of a wind power generator of a fine dust reduction system having a wind power generator according to an embodiment of the present invention.
5 is a perspective view of a rotating shaft support, which is one configuration of the wind turbines of FIGS. 3 to 4.
6 is a schematic diagram of a water supply control unit and an air induction unit of a fine dust reduction system having a wind power generator according to an embodiment of the present invention.
7 is an operation block diagram of the water supply control unit of FIG. 6.

Hereinafter, the description of the present invention with reference to the drawings is not limited to a specific embodiment, and various conversions may be applied and various embodiments may be provided. In addition, it should be understood that the contents described below include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention.

In the following description, terms such as first and second are terms used to describe various components, and are not limited in meaning to themselves, and are used only to distinguish one component from other components.

The same reference numerals used throughout this specification denote the same components.

The singular expression used in the present invention includes the plural expression unless the context clearly indicates otherwise. In addition, terms such as “include”, “have” or “have” described below are intended to indicate that there are features, numbers, steps, operations, components, parts, or combinations thereof described in the specification. It should be interpreted and understood to not preclude the existence or addition possibility of one or more other features, numbers, steps, actions, components, parts or combinations thereof.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1 to 7.

1 is a schematic diagram of a fine dust reduction system having a wind power generator according to an embodiment of the present invention, Figure 2 is an internal configuration of a water jet part of a fine dust reduction system having a wind power generator according to an embodiment of the present invention, Figure 3 is a perspective view showing the inside of the wind turbine of the fine dust reduction system having a wind power generator according to an embodiment of the present invention, Figure 4 is a fine dust reduction having a wind power generator according to an embodiment of the present invention It is a front view showing the inside of the wind power generator of the system, and FIG. 5 is a perspective view of a rotating shaft support which is one configuration of the wind power generators of FIGS. 3 to 4.

In addition, FIG. 6 is a schematic diagram of a water supply control unit and an air induction unit of a fine dust reduction system having a wind power generator according to an embodiment of the present invention, and FIG. 7 is an operation block diagram of the water supply control unit of FIG. 6.

First, referring to Figures 1 to 5, the fine dust reduction system equipped with a wind power generator according to an embodiment of the present invention is an incinerator 10, a water injection unit 100, a water collecting unit 200, an air discharge unit ( 300), a wind power generator 400, may include a water supply unit 500.

In detail, the incinerator 10 may be connected to the water injection unit 100. Here, the position of the incinerator 10 is not limited, but is generally formed to be buried underground, and will be described below based on the shape buried underground.

The incineration furnace 10 and the water injection part 100 are connected by a connection part 50, and the first to third connection parts 50-1, 50-2, and 50-3 are sequentially formed in the connection part 50. Can be.

Specifically, the first connecting portion 50-1 may be a ventilation pipe connected to the incinerator 10. In addition, the first connection portion 50-1 may be formed to be inclined upward. At this time, it is preferable that the first connecting portion 50-1 forms an inclination between 30° and 60° so that ventilation is smooth.

The second connection part 50-2 may be a ventilation pipe connecting the first connection part 50-1 and the third connection part 50-3. In addition, the second connecting portion 50-2 may be formed to vertically project from the basement to the outside.

The third connection portion 50-3 may be a ventilation pipe connected to the water injection portion 100. In addition, the third connecting portion 50-3 may be formed horizontally.

Here, the connecting portion 50 may be provided with an incineration ash filter 60 for primarily filtering large particles of dust generated in the incinerator 10, preferably the first connecting portion 50-1 formed to be inclined. It may be provided in. At this time, the incineration ash filter 60 may be provided in one or more, it is efficient to be provided in a plurality, that is, in multiple stages along the longitudinal direction of the connecting portion (50).

The water spray part 100 formed at the end of the connection part 50 may include a water spray part housing 110, a supply pipe 120, a first water spray device 130, and a discharge pipe 140.

Specifically, the water spray unit housing 110 may form a space therein. At this time, the water spray unit housing 110 may be formed in a hexahedral or cylindrical tubular form, but this is not limited, and the form may be variously changed.

The supply pipe 120 may be coupled to the inner surface of the water spray part housing 110. In addition, the supply pipe 120 is connected to the water supply unit 500 to temporarily receive water. In addition, the supply pipe 120 may be formed of one or more. At this time, the supply pipe 120, as shown in Figure 2, may be provided in the form of a circular hole formed in the center, but this is not limited as an example and the inner surface of the shape of the water jet housing 110 It may be formed in a corresponding shape.

Description of the water supply unit 500 connected to the water injection unit 100 will be described later.

The first water injection device 130 may be connected to be supported by the supply pipe 120. In addition, the first water spraying device 130 may spray water into the water spraying unit housing 110. At this time, the first water injection device 130 may include a flow pipe 132 and a spray nozzle 134, the flow pipe 132 may form a length in a spiral to allow water to flow, the spray nozzle ( A plurality of 134 may be formed along the spiral length of the flow pipe 132.

That is, the flow pipe 132 is formed in a spiral shape along the length of the water injection unit housing 110 and is a structure supported by the supply pipe 120. In this case, the flow pipe 132 may be connected to the supply pipe 120 to transfer water supplied from the water supply unit 500 through the supply pipe 120 to the injection nozzle 134.

On the other hand, the spray nozzle 134 is preferably provided so as to face the multi-faceted surface so as to collect as much as possible the fine dust mounted inside the water injection part housing 110, and is provided with a sprinkler type that is formed to have a narrow end particle diameter to diversify the water. It is preferably formed to scatter. Through this, the water spraying unit 100 can collect fine dust in the air generated during the operation of the incinerator 10 and flow it with water.

The fine dust collection discharged from the water injection unit 100 may be discharged to the collection unit 200 through the discharge pipe 140. To this end, the discharge pipe 140 is provided at the bottom of the water injection unit housing 110 may be connected to the water collection unit 200.

Meanwhile, one or more water spray units 100 may be provided. That is, as shown in FIG. 1, two water spray units 110 may be sequentially formed, and the present invention is not limited thereto and may be provided in one or three or more. Here, when two or more water spray units 100 are provided, there is an advantage of collecting dust in the air more effectively.

As described above, the fine dust collecting water discharged from the water spray unit 100 may be discharged to the water collecting part 200 through the discharge pipe 140.

At this time, the water collecting unit 200 may receive the fine dust collecting water and discharge the filtered water of the fine dust to the outside. To this end, the collection unit 200 may be connected to the outlet 210, which can be discharged to the outside.

That is, the water collecting unit 200 is connected to the discharge pipe 140 to receive and receive the water sprayed from the water injection unit 100, and at the same time discharge water through the outlet 210 formed on the top. At this time, since the outlet 210 is located at the top, fine dust is filtered to sink to the bottom, and only clean water can be discharged out.

In addition, since it is preferable that the water collection well is generally buried underground, the water collecting part 200 of the fine dust reduction system having a wind power generator according to an embodiment of the present invention may also be buried underground. That is, the water collecting unit 200 may receive the fine dust collecting water discharged from the water spray unit 100 buried underground and formed on the ground and discharge it to the outlet 210 formed underground. At this time, since the fine dust is filtered in the first collection well 200, the fine dust may not be exposed to the outside.

On the other hand, the collection unit 200 may be formed of one or two, it may also be formed of three as shown in FIG. That is, the collecting unit 200 may be provided with one or more in accordance with the conditions such as the amount of fine dust generated from the incinerator. This is a principle similar to that of the water spray unit 100, and the more the water collecting part 200 is provided, the more advantageous it is to perform filtration, and this can also be attributed to soil pollution prevention.

Here, when two or more of the water collecting part 200 is provided, the water collecting part 200 may be connected through the water collecting part connection pipe 220, and the water collecting part connection pipe 220 may be formed on the upper portion as well as the outlet 210. Preferably, the sump connection pipe 220 and the outlet 210 may be formed on the same straight line.

The air discharge unit 300 may be connected to the water injection unit 100. In addition, the air discharge unit 300 may be formed in the longitudinal direction toward the upper side to discharge the air that has passed through the water injection unit 100 to the outside.

At this time, a second water spray device 310 is provided at the bottom of the air discharge part 300 to collect fine dust that has passed through the water spray part 100. That is, the fine dust reduction system according to an embodiment of the present invention may form a plurality of dust collecting structures to collect fine dust, which forms one or more water spray units 100 as described above, and finally discharges air It may be made through a second water spraying device 310 provided at the bottom of the unit 300.

Here, the second water injection device 310 may be provided as a sprinkler type similar to the first water injection device 130, but is not limited, and may be formed to perform high pressure injection in consideration of the length of the air discharge unit 300. have.

In addition, the air discharge unit 300, like the water injection unit 100, may be connected to the water collection unit 200 to discharge fine dust collection, specifically, the water injection unit 100 at the bottom of the air discharge unit 300 The discharge pipe 140 connecting the water collecting part 200 with the water may be extended to be connected to the water collecting part 200.

Through such a plurality of dust collecting structures, the fine dust reduction system according to an embodiment of the present invention can discharge more clean air to the outside.

Meanwhile, the wind power generator 400 may be provided at the top of the air discharge unit 300 to generate power using air discharged from the air discharge unit 300. In addition, the wind power generator 400 may generate power using external wind at the same time.

To this end, the wind power generator 400 may include a rotating shaft 410, a support portion 420, a wing portion 430, a support portion 440, and a driving portion 450 as shown in FIGS. 3 to 4. .

Specifically, the rotating shaft 410 may connect the wing part 430 and the driving part 450. The wing part 430 may operate the driving part 450 by rotating the rotating shaft 410 using air discharged from the air discharge part 300, and the driving part 450 may be operated to produce electricity. The detailed description of the wing portion 430 and the driving portion 450 will be described later.

In addition, an industrial diamond 415 may be provided at an end of the rotating shaft 410 on the wing 430 side. This minimizes friction with the rotating shaft support 431 of the wing portion 430 supporting the rotating shaft 410, and is configured to easily rotate without parts such as bearings. Detailed description will be given later in the description of the wing portion 430. I will do it.

The support part 420 may be coupled to the air discharge part 300 outside the upper part. At this time, the support portion 420 may be formed in a hollow cylindrical interior so as to be combined with the air discharge portion 300. A wing portion 430 may be provided on the upper side of the supporting portion 420.

The wing portion 430 may be formed to rotate by the discharged air. To this end, the wing portion 430 may include a rotating shaft support 431, an inner mechanism wing 432, and a wing portion housing 433.

In detail, the rotation shaft support 431 may be attached to the top and bottom of the wing portion 430 to support the rotation shaft 410 for rotating the inner mechanism wing 432. In addition, the rotation shaft support 431 may be formed to support the rotation shaft 410 and to pass air discharged from the air discharge unit 300. To this end, as shown in FIG. 5, the rotation shaft support 431 may be formed such that a plurality of rotation shaft support bars 431-1 are spaced apart to form a vent hole 431-2.

Here, the rotation shaft support 431 attached to the lower end of the wing portion 430 may be formed to rotate in line contact with the rotation shaft 410. This can be achieved by providing an industrial diamond 415 at the end of the wing portion 430 side of the rotating shaft 410 as described above, wherein the industrial diamond 415 is formed in a conical shape and the rotating shaft support 431 It can be pre-contacted.

When the rotating shaft 410 rotates in line with the rotating shaft support 431, the amount of wear is significantly reduced compared to the surface contact, and rotation can be easily performed without accessories such as bearings.

At this time, the line contact is made of industrial diamonds having high hardness, high thermal conductivity, low coefficient of thermal expansion, and high acid resistance, so there is no room for thermal deformation or damage even when used for a long time at the top of the air exhaust section 300 where high heat rises. Because it is small, it can rotate smoothly.

On the other hand, the rotating shaft support 431 at the lower end of the wing portion 430 is preferably formed of industrial diamond having the same hardness as the contact portion with the rotating shaft 410 so as not to wear when in contact with industrial diamond.

Through this, the rotating shaft 410 is easy to rotate without accessories such as bearings, and may have an advantage of being able to rotate for a long time.

The inner mechanism wing 432 may be formed along the outer periphery of the rotating shaft between the rotating shaft supports 431. In addition, the inner mechanism wing 432 may be formed in a spiral. This is a structure for guiding air upward while simultaneously obtaining rotational force through air discharged from the air discharge unit 300.

At this time, the rotational force may be largely formed by the temperature difference between the air discharge unit 300 and the outside. That is, since the high temperature air is rapidly discharged to the outside due to the temperature difference between the high temperature air discharged from the air discharge unit 300 and the low temperature air formed outside, the rotational force can be formed more strongly.

A wing housing 433 may be provided on the outer side of the inner working wing 432 to surround the inner working wing 432. Here, the wing housing 433 is formed between the two rotating shaft supports to prevent leakage of air from the air discharge unit 300 to the side of the inner wing 432 of the air. That is, since the wing housing 433 is provided, the inner drive wing 432 can be protected from the outside, and guides the air of the air discharge unit 300 upwards, and at the same time, obtains rotational force.

Meanwhile, a support part 440 may be formed on the upper side of the wing part 430, and specifically, the support part 440 may include a driving part support bar 442 and an external mechanism wing 444.

The driving part support bar 442 is a means for supporting the driving part 450 provided at the top of the wind power generator, and at least three may be formed.

At this time, the rotating shaft 410 connecting the wing portion 430 and the driving portion 450 may be exposed between the driving portion support bars 442, that is, the rotating shaft portion of the supporting portion 440, that is, the wing portion 430 and the driving portion. A screw-shaped external mechanism wing 432 may be attached to the outer circumference of the rotating shaft between 450. This is to increase the rotational force through the wind blowing from the outside, the outer mechanism wing 444 receives the wind blowing from the outside in addition to the rotational force of the air guided from the wing portion 430, the rotational force of the rotating shaft 410 Can be increased.

The driving part 450 is supported by the support part 440 as described above, and may be provided at the top end of the wind power generator. In addition, the driving unit 450 may be connected to the wing unit 430 through the rotation shaft 410 and may be generated by the rotational force of the wing unit 430.

To this end, the drive unit 450 includes a drive unit housing 451, an internal gear 452, a rotating plate 454, a transmission gear 455, a generator gear 457, a generator 460, a storage battery 470, a generator housing ( 480).

Specifically, the driving unit housing 451 is a body of the driving unit 450 supported by the supporting unit 440, and may form a space therein.

The internal gear 452 may be formed along one inner circumferential surface of the driving unit housing 451.

The rotating plate 454 may be coupled to the rotating shaft 410 and connected to the internal gear 452. At this time, the rotating plate 454 is formed on the lower end of the internal gear 452 and is coupled to the rotating shaft 410 and may be formed to be connected to the internal gear 452. Through this, the internal gear 452 may rotate by rotation of the rotation shaft 410.

The transmission gear 455 may mesh with the internal gear 452. Here, the transmission gear 455 may be provided with two as shown in Figure 3, but this is not limited as an example, it may be formed of one or more than three.

That is, the transmission gear 455 is configured to modify the rotation ratio of the internal gear 452, and it is preferable that the number is determined according to the size or torque of the wind power generator. Through this, the transmission gear 455 can generate a faster rotational force by changing the rotation ratio of the internal gear 452.

A generator gear 457 may be meshed with the transmission gear 455. Also, the generator gear 457 may be connected to the generator 460.

That is, the rotational force of the rotating shaft 410 is sequentially transmitted through the rotating plate 454 and the internal gear 452, and the rotational force transmitted to the internal gear 452 is a generator gear through a transmission gear 455 provided with one or more. It can be accelerated to 457 and delivered. At this time, the generator 460 is connected to the generator 457, so that the generator 460 can produce electricity according to the increased rotational force.

Meanwhile, the generator 460 may be connected to the storage battery 470 to store electricity produced.

The generator housing 480 may be formed to embed the generator 460 and the storage battery 470. That is, the generator 460 and the storage battery 470 are protected by the generator housing 480 and may not be exposed to the outside.

By providing the above-described wind power generator, the fine dust reduction system according to an embodiment of the present invention has the advantage of being able to use air more efficiently while making and discharging clean air.

In addition, the water supply unit 500 may be connected to the water injection unit 100 to supply water to the water injection unit 100. To this end, the water supply unit 500 includes a water tank 510 and a water pump 520, and the water injection unit 100 receives water from the water tank 510 by the water pump 520 as a first water injection device. (130).

Meanwhile, referring to FIGS. 6 to 7, a fine dust reduction system including a wind power generator according to an embodiment of the present invention may further include a water supply control part 600 and an air induction part 700.

Specifically, the water supply control unit 600 may measure the concentration of fine dust to adjust the water supply amount of the water supply unit. To this end, a concentration sensor 610 and a control unit 620 may be included.

In detail, the concentration sensor 610 may be installed under the water collecting part 200. In addition, the concentration sensor 610 may exchange signals with the control unit 620 interlocked with the water pump 520 of the water supply unit 500. That is, the concentration sensor 610 measures the fine dust concentration of the fine dust collection number accommodated in the water collecting part 200 and transmits a measurement signal to the control unit 620, and the control unit 620 measures from the concentration sensor 610 By receiving a signal, the pump amount of the water pump 520 can be controlled.

Through this, the water supply control unit 600 can easily cope with the occurrence of a large amount of fine dust by adjusting the water injection amount of the water injection unit 100 according to the concentration of fine dust.

On the other hand, when two or more water collecting parts 200 are provided, the concentration sensor 610 is preferably installed in the water collecting part 200 formed first.

The air induction unit 700 may be provided on the air discharge unit 300 to induce air to be rapidly discharged. To this end, the air induction unit 700 may include a rotating fan 710 and a motor 720.

Specifically, the air discharge unit 300 may be formed of a chimney of about 100m in general due to the nature of being installed in the process system of the power generation facility. At this time, due to the large height, there is room for low wind power delivered to the wind power generator. Accordingly, by rotating the rotating fan 710 and the motor 720 at the upper portion of the air discharge portion 300, the air rising from the lower portion of the air discharge portion 300 can be discharged more quickly, and through this, the wind generator Air with a stronger air volume may be supplied to the 400, thereby increasing the efficiency of the wind power generator.

The above-described fine dust reduction system having a wind power generator according to an embodiment of the present invention has an advantage of effectively collecting fine dust of a process system in which an incinerator is installed by forming at least two water injection systems. Equipped with the above-mentioned water collecting section, it has the advantage of effectively filtering out fine dust from the collection of fine dust and sending only clean water out.It is equipped with a wind power generator at the end of the air exhaust section of the process system to provide clean air from which fine dust is collected and discharged. By making it possible to develop through, it has the advantage of using energy more effectively.

The embodiments of the present invention have been described with reference to the accompanying drawings, but a person having ordinary knowledge in the technical field to which the present invention pertains may be implemented in other specific forms without changing the technical spirit or essential features of the present invention. You will understand. Therefore, the above-described embodiment is illustrative in all respects and is not limiting.

10: incineration furnace
50: connection
60: incineration ash strainer
100: water spray unit
110: water spray housing
120: supply pipe
130: first water spray device
132: flow pipe
134: spray nozzle
140: discharge pipe
200: catchment government
210: outlet
220: water collector connector
300: air outlet
310: second water spray device
400: wind power generator
410: rotating shaft
415: industrial diamond
420: base
430: wing
431: rotating shaft support
431-1: Rotation shaft support bar
431-2: Ventilator
432: internal mechanism wing
433: wing housing
440: support
442: drive part support bar
444: external mechanism wing
450: driving unit
451: drive unit housing
452: inscribed gear
454: rotating plate
455: Transmission gear
457: generator language
460: generator
470: storage battery
480: generator housing
500: water supply unit
510: water tank
520: water pump
600: water supply control unit
610: concentration sensor
620: control unit
700: air induction
710: rotating fan
720: motor

Claims (12)

It is connected to the incinerator, one or more water spray unit for spraying water to collect the fine dust generated by the action of the incinerator;
At least one collecting unit connected to the water injection unit to receive dust-collected water from the water injection unit and discharge dust-filtered water to the outside;
An air discharge part connected to the water spray part to form a longitudinal direction upward, and exhausting air passing through the water spray part to the outside;
A wind power generator provided at the top of the air discharge unit and operated by using the discharged air and external wind, and
It has a wind power generator including a water supply for supplying water to the water injection unit,
The wind turbine,
A support portion coupled to the upper side of the air discharge portion;
A wing portion formed above the support portion to generate rotational force with air discharged from the air discharge portion;
It is formed above the wing portion, is exposed to the outside to accommodate the outside air support portion for increasing the rotational force and
It is provided at the top end includes a driving unit that generates power by the rotational force transmitted from the wing and the support,
The driving unit and the wing portion fine dust reduction system having a wind turbine, characterized in that connected by a single rotating shaft.
According to claim 1,
The water injection unit,
A water spray part housing forming a space therein;
One or more supply pipes coupled to the inner surface of the water injection unit housing, connected to the water supply unit to receive water;
A first water spraying device connected to be supported by the supply pipe and spraying water into the water spray part housing;
It is provided at the bottom of the housing of the water injection unit and is connected to the water collecting portion includes a discharge pipe for transmitting fine dust collection,
The first water spray,
A flow pipe through which water flows by forming a length in a spiral and
A fine dust reduction system having a wind power generator including a plurality of injection nozzles formed on the flow pipe.
According to claim 1,
The air discharge unit,
A second water spraying device is provided at the bottom to collect fine dust passing through the water spraying part, and the bottom of the air discharge part is connected to the water collecting part so as to discharge water from the second water spraying device. Fine dust reduction system equipped with a wind power generator.
delete According to claim 1,
The wing portion,
Two rotation shaft support is attached to the upper and lower wings, and is formed to support the rotation shaft while passing the wind of the air discharge unit;
Helical inner wing formed along the outer periphery of the rotating shaft between the two rotating shaft support and
A fine dust reduction system including a wind power generator including a wing housing formed between the two rotating shaft supports so as to surround the outer side of the inner mechanism blade.
According to claim 1,
The rotating shaft,
A fine dust reduction system having a wind power generator, characterized in that, by providing a cone-shaped industrial diamond at the lower end of the wing portion, the blade is rotated by minimizing friction by linear contact with the lower shaft support.
According to claim 1,
The support portion,
At least three driving part support bars supporting the driving part, and
It is formed along the length of the axis of rotation between the drive unit and the wing, and includes an external mechanism wing formed in the form of a screw,
The rotating shaft is a fine dust reduction system having a wind power generator, characterized in that the rotational force can be increased by external wind by an external mechanism wing.
According to claim 1,
The driving unit,
A driving unit housing forming a space therein;
An internal gear formed along one inner circumferential surface of the driving unit housing;
A rotating plate coupled to the rotating shaft and connected to the internal gear;
A transmission gear meshing with the internal gear;
A generator gear meshing with the transmission gear;
A generator connected to the generator gear to generate electricity;
A storage battery connected to the generator to store electricity in the generator;
A fine dust reduction system having a wind power generator including a generator housing incorporating the generator and the storage battery.
According to claim 1,
The water supply unit,
A fine dust reduction system including a water tank and a water pump, comprising a wind generator characterized in that it is connected to the water injection unit.
According to claim 1,
A fine dust abatement system with a wind power generator, characterized in that an incineration ash filter is provided at a connection portion connecting the incinerator and the water injection section.
According to claim 1,
The fine dust reduction system having the wind power generator,
It further includes a water supply control unit including a concentration sensor and a control unit,
The concentration sensor,
It is installed at the bottom of the water collecting section to interlock with the control unit, measure the concentration of fine dust, and transmit it to the control unit.
The control unit is a fine dust reduction system having a wind power generator, characterized in that for adjusting the water supply amount of the water supply in accordance with the concentration of the fine dust measured from the concentration sensor.
According to claim 1,
The fine dust reduction system having the wind power generator,
Further comprising an air induction portion installed on the air outlet portion,
The air induction unit, including a rotating fan and a motor, a fine dust reduction system having a wind turbine characterized in that it can be induced to quickly discharge air.

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