KR101239548B1 - Rotary feed apparatus for a combustion system of solid fuel - Google Patents

Abstract

The present invention relates to a rotary feeder device for a biomass combustion system, wherein a part of the solid biomass fuel quantitatively supplied by the rotary feeder flows in one direction from the inside of the conveying pipe of the compressed air transfer unit to the other inside of the compressed air conveying unit. It is possible to more easily prevent the possibility of rising by passing through the inside of the rotary feeder and discharged to the outside, and bottlenecks are not generated inside the rotary feeder, so that the solid biomass fuel is lowered by the rotary feeder. There is an effect that can be more quantitatively supplied.

Compressed air inlet, compressed air exhaust

Description

ROTARY FEED APPARATUS FOR A COMBUSTION SYSTEM OF SOLID FUEL}

In the present invention, a portion of the solid biomass fuel quantitatively supplied by the rotary feeder is lifted by the high-pressure compressed air flowing in one direction from the inside of the feed pipe of the compressed air transfer part to the other side and discharged through the inside of the rotary feeder to the outside. For biomass combustion system that can more easily prevent the possibility of becoming a bottleneck, and bottlenecks are not generated in the rotary feeder, so that the solid biomass fuel can be more quantitatively supplied downward more smoothly by the rotary feeder. It relates to a rotary feeder device.

Generally, in order to cope with the United Nations Framework Convention on Climate Change, cogeneration of wood obtained through natural or timber that is naturally discarded in nature, such as Sweden and Austria, which are rich in forest resources, It is actively used as a fuel for power generation.

In addition, in the UK, wood, reeds, and corn stalks are actively used as cogeneration fuels. In Korea, wood is used as a fuel made of chips and currently used as cogeneration fuels in Seodaegu Industrial Complex.

In addition, as Kyoto's sentiment was officially entered into force in February 2005, countries around the world are striving to develop and disseminate renewable energy, a fundamental measure to reduce greenhouse gas emissions.

Major industrial developed countries in Europe have been promoting renewable energy commercialization policies since the early 1990s, resulting in up to 50% of thermal energy demand in biomass-fired biomass combustion systems.

Wood biomass woodchips (wood biomass woodchips) contains ash content of 3 ~ 5wt%, but there is no technical problem to use as fuel, and because the low moisture content does not require a separate drying process, its use is increasing day by day. It is a trend.

Among the unit facilities in the biomass combustion system, a transfer screw, a rotary feeder, and the like are widely used, and a turbine boiler and the like are generally used in a combustion chamber.

Among these, the biomass combustion system rotary feeder device as shown in FIG. 1 is large, a solid biomass fuel is accommodated therein, and an accommodating part 310 in which one side and the other side plates 301 and 303 are vertically fixed on both sides, respectively. )Wow;

A rotating shaft 330 provided inside the accommodating part 310 in a state where both ends thereof are axially coupled to one side and the other side plates 301 and 303 of the accommodating part 310;

It is provided at equal intervals on the outer periphery of the rotary shaft 330, so that the solid biomass fuel contained in the interior of the receiving portion 310 can be quantitatively supplied into the feed pipe 500 of the compressed air transfer unit 50 It comprises a; rotating blade 350 to rotate along the rotating shaft 330 to quantitatively supply the solid biomass fuel received in the interior of the receiving portion 310 in the downward direction.

The solid biomass fuel quantitatively supplied by the rotating blade 350 flows into the transfer pipe 500 of the compressed air transfer part 50 and is supplied in the other direction from the inner side of the transfer pipe 500. The high pressure compressed air is supplied to the combustion chamber (not shown) along the transfer pipe 500.

However, some of the solid biomass fuel quantitatively supplied by the rotary blade 350 in the lower direction of the rotary feeder 30 by the high-pressure compressed air flowing from one inner side of the transfer pipe 500 to the other inner direction There is a problem that is raised to the inside and discharged to the outside.

In addition, since the solid biomass fuel is loaded into the stepped groove 302 formed in a predetermined depth in one surface of the receiving portion 310 and the inner circumferential surface F of the other side plates 301 and 303, the rotating blade 350 is loaded. There is a problem that the so-called bottlenecks are blocked by the solid biomass fuel is not smoothly supplied in the downward direction.

The present invention was created in order to solve the above-mentioned problems, and a portion of the solid biomass fuel quantitatively supplied by the rotary feeder flows in the high pressure compressed air flowing in one direction from the inside of the feed pipe of the compressed air transfer part to the other side. It is possible to more easily prevent the possibility of rising by passing through the inside of the rotary feeder and discharged to the outside, and the bottleneck does not occur inside the rotary feeder, so that the solid biomass fuel is further lowered by the rotary feeder. It is an object of the present invention to provide a rotary feeder device for a biomass combustion system that can be quantitatively supplied smoothly.

The present invention for achieving the above object is a rotary feeder for a biomass combustion system comprising a rotary feeder for quantitatively supplying the solid biomass fuel into the conveying pipe of the compressed air transfer unit for transferring the solid biomass fuel to the combustion chamber of the boiler. In the apparatus, a portion of the high-pressure compressed air passing through the inner one side of the transfer pipe 50 having a pressure larger than the high-pressure compressed air passing through the other inside of the transfer pipe 50 at one end of the transfer pipe Compressed air inflows are provided, and both sides of the rotary feeder are connected to the compressed air inflows, respectively, and compressed air discharges respectively discharge some of the high pressure compressed air introduced into the compressed air inflows into the rotary feeder. Provided is a rotary feeder device for a biomass combustion system, characterized in that each ball is formed.

Here, the rotary feeder is a solid biomass fuel is accommodated therein, the receiving portion is fixed to one side and the other side of the vertical plate on each side; A rotating shaft provided inside the accommodating part in a state in which both ends thereof are axially coupled to one side and the other side plate of the accommodating part; It is provided at the outer periphery of the rotary shaft at equal intervals, the solid biomass fuel contained in the receiving portion is rotated along the rotating shaft so that the fixed quantity can be supplied into the transfer pipe lower the solid biomass fuel contained within the receiving portion Rotation blade for quantitatively supply in the direction; is configured to include, the compressed air discharge hole is connected to the compressed air inlet portion on the one side and the other side plate is preferably formed respectively.

Further, the scraper extending in the direction of the inner circumferential surface of the one side and the other side of the accommodating portion is formed on the upper side and the lower side of the rotating blade, respectively, the inner peripheral surface of the one side and the other side of the accommodating portion is formed perpendicularly desirable.

In addition, the sensor provided on the inner circumferential surface of the inlet formed on the upper side of the receiving portion for detecting the solid biomass fuel received at a predetermined height inside the receiving portion; A drive motor axially coupled to the rotating shaft to forward and reverse rotate the rotating shaft a predetermined number of times; According to the signal output from the sensor it is preferable that the control unit for controlling the drive motor so that the drive motor rotates forward and backward the rotation axis a predetermined number.

In addition, it is preferable that the foreign material discharge pipe for discharging the foreign matter heavier than the solid biomass fuel contained in the solid biomass fuel in the lower direction in the lower portion of the transfer pipe to communicate with the transfer pipe vertically.

According to the present invention, a part of the high pressure compressed air passing through the inner one side of the transfer pipe having a greater pressure than the high pressure compressed air passing through the other side of the transfer pipe is introduced into the compressed air inlet provided at one end of the transfer pipe. After being discharged to the inside of the rotary feeder through the compressed air discharge holes formed on both sides of the rotary feeder, some of the solid biomass fuel quantitatively supplied to the inside of the transfer pipe is internally disposed at one side of the transfer pipe. There is an effect that it is possible to more easily prevent the possibility of rising by the high-pressure compressed air flowing in the other direction passing through the inside of the rotary feeder to the outside.

In addition, since the rotary feeder is configured to include a receiving part, a rotating shaft, and a rotating blade, the rotary feeder can more easily quantitatively supply solid biomass fuel into the conveying pipe as well as perpendicular to both sides of the receiving part. As the compressed air discharge hole connected to the compressed air inlet is formed on one side of the fixed side and the other side plate, the compressed air of some high pressure may be more easily discharged into the rotary feeder.

In addition, since the inner circumferential surface of one side and the other side plate of the receiving portion is vertically formed vertically, a part of the solid biomass fuel supplied by the rotating blade downward is not loaded around the inner circumferential surface of the one side and the other side plate as well. Due to this, the solid biomass fuel can be more quantitatively supplied more smoothly in the downward direction by the rotary blade, that is, the bottleneck does not occur in the rotary feeder.

Furthermore, since the drive motor rotates the rotating shaft forward and backward by a predetermined number of times under the control of the control unit according to the signal output from the detection sensor, the rotating blade can intermittently supply the biomass fuel in the lower direction more easily and intermittently. It is effective.

In addition, there is an effect that it is possible to more easily separate foreign matters such as metal material having a larger weight and larger size than the solid biomass fuel contained in the solid biomass fuel through the foreign matter discharge pipe provided in the lower portion of the transfer pipe. .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

2 is a cross-sectional view schematically showing a rotary feeder device for a biomass combustion system according to an embodiment of the present invention.

Rotary feeder device for a biomass combustion system of one embodiment of the present invention as shown in Figure 2, largely comprises a rotary feeder 30 and the compressed air transfer unit (50).

First, the rotary feeder 30 is for quantitatively supplying solid biomass fuel including waste wood chips, waste plastic chips, etc. into the delivery pipe 500 of the compressed air transfer unit 50.

Next, the compressed air transfer unit 50 is for transferring the solid biomass fuel quantitatively supplied by the rotary feeder 30 to a combustion chamber (not shown) such as a turbine boiler.

The compressed air transfer unit 50 may be largely configured to include a transfer pipe 500 and a high pressure air supply unit 510.

The transfer pipe 500 may be connected to a combustion chamber (not shown) such as a turbine boiler.

The transfer pipe 500 may be horizontally provided in the left and right directions below the rotary feeder 30.

The upper side of the center of the transfer pipe 500 may be in communication with the lower portion of the rotary feeder (30).

The high pressure air supply unit 510 may be provided at one side of the transfer pipe 500 to supply high-pressure compressed air from one side of the inside of the transfer pipe 500 to the other inside.

As the high pressure air supply unit 510, a blowing fan may be used, but the present invention is not limited thereto, and any high pressure air supply unit 510 may be used as long as it can supply high pressure compressed air from one inner side of the transfer pipe 500 to the other inner side. Can be.

On the other hand, the pressure of the high-pressure compressed air (P ₁ of FIG. 4) passing through the inner side of the transfer pipe 500 relative to the rotary feeder 30 passes through the other inner side of the transfer pipe 500 relatively. It is larger than the pressure of the high pressure compressed air (P ₂ of FIG. 4). (P ₁ > P ₂ )

Here, in particular, as shown in Figure 2, one end of the transfer pipe 500 is provided with a compressed air inlet 530.

In the compressed air inlet 530, some of the high pressure compressed air passing through the inner one side of the transfer pipe 500 is larger than the high pressure compressed air passing through the other side of the transfer pipe 500. do.

In addition, compressed air discharge holes 311 and 313 are formed at both sides of the rotary feeder 30, respectively.

The compressed air discharge holes 311 and 313 are connected to the compressed air inlet 530.

The compressed air discharge holes 311 and 313 discharge some of the high pressure compressed air introduced into the compressed air inlet 530 into the rotary feeder 30, respectively.

More specifically, the compressed air inlet 530 may be largely composed of first and second compressed air inlet members 531 and 533.

The first and second compressed air inflow members 531 and 533 may be made of a pipe such as a metal material or a hose such as a synthetic resin, but is not necessarily limited thereto.

However, in the present invention, the first and second compressed air inflow members 531 and 533 will be described in detail with an example made of a hose made of synthetic resin or the like.

One end of the first compressed air inlet member 531 made of a hose, such as a synthetic resin material can be securely connected to the compressed air inlet hole 501 formed on the outer periphery of one end of the transfer pipe 500. have.

The other end of the first compressed air inflow member 531 made of a synthetic resin material hose or the like may be hermetically connected to the compressed air discharge hole 311 formed at one side of the rotary feeder 30.

One end of the second compressed air inflow member 533 made of a synthetic resin material hose or the like may be hermetically communicated with an upper end of the other end of the first compressed air inflow member 531.

The other end of the second compressed air inflow member 533 made of a synthetic resin material hose or the like may be hermetically connected to the compressed air discharge hole 313 formed at the other side of the rotary feeder 30.

Some of the high pressure compressed air passing through the inner one side of the transfer pipe 500 having a greater pressure than the high pressure compressed air passing through the other inner side of the transfer pipe 500 is the compressed air inlet hole 501, the first , 2 compressed air inlet members (531, 533) and the compressed air discharge holes (311, 313) are sequentially discharged into the inside of the rotary feeder 30 (see dotted arrows in Fig. 4).

As described above, some of the high pressure compressed air passing through the inner one side of the transfer pipe 500 having a greater pressure than the high pressure compressed air passing through the other side of the transfer pipe 500 is the transfer pipe 500. After being introduced into the compressed air inlet 530 provided at one end of the rotary air feeder through the compressed air discharge holes 311 and 313 respectively formed on both sides of the rotary feeder 30. Part of the solid biomass fuel quantitatively supplied to the inside of the transfer pipe 500 as it is discharged by the high-pressure compressed air flowing in the other direction from the inner side of the transfer tube 500, so that the rotary feeder (30) There is an advantage that it is possible to more easily prevent the risk of being discharged to the outside through the inside.

3 is a cross-sectional view taken along line AA of FIG. 2.

Next, as shown in FIGS. 2 and 3, the rotary feeder 30 may include a receiving part 310, a rotation shaft 330, and a rotation blade 350.

The solid biomass fuel 11 may be accommodated in the accommodation portion 310.

One side and the other side plates 301 and 303 may be vertically fixed to both sides of the accommodation part 310 by fastening members 13 such as bolts.

An inlet 315 into which the solid biomass fuel 11 is input may be formed at an upper side of the accommodation part 310.

A discharge port 317 may be formed at a lower side of the accommodating part 310 to communicate with an upper portion of the central portion of the transfer pipe 500 to discharge the solid biomass fuel 11 into the transfer pipe 500.

The rotation shaft 330 may be horizontally provided in the left and right directions inside the accommodating part 310 in a state where both ends are axially coupled to the center of one side and the other side plates 301 and 303 of the accommodating part 310, respectively. .

4 is a cross-sectional view schematically illustrating a state in which the solid biomass fuel 11 in the transfer pipe 500 is supplied to the combustion chamber (not shown) along the transfer pipe 500 by high pressure compressed air.

The rotating blade 350 may be provided at equal intervals on the outer circumference of the rotating shaft 330 in a state extending in the longitudinal direction of the rotating shaft 330.

The rotary blade 350 is along the rotating shaft 330 so that the solid biomass fuel 11 accommodated in the receiving portion 310 can be quantitatively supplied into the transfer pipe 500 as shown in FIG. 4. Reverse rotation may quantitatively supply the solid biomass fuel 11 accommodated at a predetermined height inside the receiving portion 310 in the downward direction.

The compressed air discharge holes 311 and 313 connected to the compressed air inlet part 530 may be formed at one side of the receiving part 310 and the upper side of the other side plates 301 and 303, respectively.

Since the rotary feeder 30 includes the accommodating part 310, the rotating shaft 330, and the rotating blade 350, the rotary feeder 30 is a solid biomass fuel 11 into the transfer pipe 500. In addition to being able to more easily quantitatively supply) is connected to the compressed air inlet 530 to the upper side of the one and the other side plate (301, 303) that is vertically fixed to both sides of the receiving portion 310, respectively As the compressed air discharge holes 311 and 313 are formed, some of the high pressure compressed air may be more easily discharged into the rotary feeder 30.

Next, as shown in FIG. 2 and FIG. 4, the scraper extending in the direction of the inner circumferential surface of the one side and the other side plate (301, 303) of the receiving portion 310 on the upper side and the lower side of the rotating blade 350. 305 and 307 may be protruded, respectively.

The scrapers 305 and 307 rotate in the forward and reverse directions along the rotating blade 350 and partially solid biomass fuel remaining on the inner circumferential surface F of one side of the receiving portion 310 and the other side plates 301 and 303 ( 11) can be scraped and forced to the downward direction.

2 and 4, the inner circumferential surface F of one side of the accommodating part 310 and the other side plates 301 and 303 is flat without stepped grooves 302 of FIG. 1 recessed to a certain depth. Can be vertically formed.

Since the inner surface (F) of the one side of the receiving portion 310 and the inner circumferential surface (F) of the other side plate (301, 303) is vertically formed in the solid biomass fuel 11 that the rotary blade 350 is quantitatively supplied in the downward direction A part is not loaded around the inner circumferential surface of the one side and the other side plate (301, 303), of course, so that the solid biomass fuel 11 can be more quantitatively supplied by the rotary blade 350 in the downward direction more smoothly. That is, there is an advantage that the bottleneck does not occur inside the rotary feeder 30.

Next, as shown in FIGS. 2 and 4 are provided on one side inner circumferential surface or the other inner circumferential surface of the inlet 315 formed on the upper side of the accommodating portion 310 is accommodated at a predetermined height inside the accommodating portion 10 A detection sensor 320 for detecting the solid biomass fuel 11;

A drive motor 340 horizontally coupled to one end or the other end of the rotation shaft 330 to forward and reverse rotation of the rotation shaft 330 at a predetermined number of times;

A control unit (not shown) for controlling the driving motor 340 so that the driving motor 340 rotates the rotating shaft 330 forward and backward at a predetermined number of times according to a signal output from the detection sensor 320. Can be.

The rotary blade 350 is solid because the driving motor 340 rotates the rotary shaft 330 a predetermined number of times by the control of the controller (not shown) according to the signal output from the sensor 320. There is an advantage that the biomass fuel 11 can be quantitatively more easily supplied intermittently in the downward direction.

Next, as shown in FIGS. 2 and 4, the lower portion of the transfer pipe 500 has a lower portion than the solid biomass fuel 11 included in the solid biomass fuel 11 such as waste wood chips and waste plastic chips. The foreign matter discharge pipe 550 for discharging the foreign matter 15 such as a heavy metal material and a large size downward may be vertically provided.

The upper end of the foreign substance discharge pipe 550 may be in communication with the lower portion of the central portion of the transfer pipe (500).

Here, the strength of the high-pressure compressed air supplied by the high-pressure air supply unit 510 from the inner side of the transfer pipe 500 to the inner side of the transfer pipe 500 may be a solid biomass fuel 11 such as waste wood chips or waste plastic chips. While the transfer pipe 500 can be moved inside the other direction,

Heavy foreign matter 15 contained in solid biomass fuel 11, such as waste wood chips and waste plastic chips, is sufficient to be unable to move in the other direction of the inside of the transfer pipe 500.

Foreign substances such as metal materials having a heavier weight and larger size than the solid biomass fuel 11 included in the solid biomass fuel 11 quantitatively supplied to the inside of the transfer pipe 500 by the rotary feeder 30 ( 15 is dropped into the foreign substance discharge pipe 550 by its own weight.

Although not shown in the drawing, the lower end of the foreign substance discharge pipe 550 may be connected to a separate container, and the foreign matter 15 falling downward along the foreign substance discharge pipe 550 may be collected in the separate container. .

Foreign substances such as metal materials having a heavier weight and larger size than the solid biomass fuel 11 included in the solid biomass fuel 11 through the foreign substance discharge pipe 550 vertically provided at the lower portion of the transfer pipe 500 ( There is an advantage that can be separated more easily 15).

1 is a cross-sectional view schematically showing a rotary feeder device for a conventional biomass combustion system,

2 is a cross-sectional view schematically showing a rotary feeder device for a biomass combustion system according to one embodiment of the present invention;

3 is a cross-sectional view taken along line AA of FIG. 2,

4 is a cross-sectional view schematically illustrating a state in which the solid biomass fuel in the delivery pipe is supplied to the combustion chamber along the delivery pipe by the high pressure compressed air.

*** Explanation of symbols for main parts of drawing ***

11; Solid biomass fuel, 13; Fastening member,

15; Foreign body, 30; Rotary feeder,

301; One side plate, 302; Groove,

303; Other side plates, 305 and 307; scraper

310; Receptacle, 311, 313; Compressed air exhaust,

315; Inlet, 317; outlet,

320; Detection sensor, 330; Rotation axis,

340; Drive motor, 350; Rotating Blade,

50; Compressed air transfer unit, 500; Transfer Pipe,

501; Compressed air inlet hole, 510; High pressure air supply,

530; Compressed air inlet, 531; The first compressed air inflow member,

533; A second compressed air inflow member, 550; Foreign substance discharge line.

Claims (5)

Biomass combustion comprising a rotary feeder 30 for quantitatively supplying the solid biomass fuel 11 into the delivery pipe 500 of the compressed air transfer unit 50 for transferring the solid biomass fuel 11 to the combustion chamber of the boiler. In the rotary feeder device for the system, One end of the conveying pipe 500 is a portion of the high-pressure compressed air passing through the inner one side of the conveying pipe 500 is greater than the high pressure compressed air passing through the other side of the conveying pipe 500 is introduced Compressed air inlet 530 is provided, Both sides of the rotary feeder 30 are connected to the compressed air inlet 530, respectively, and discharge some of the high pressure compressed air introduced into the compressed air inlet 530 into the rotary feeder 30, respectively. Compressed air discharge holes (311, 313) are respectively formed, The rotary feeder 30 has a solid biomass fuel 11 is accommodated therein, the receiving portion 310 is vertically fixed on one side and the other side plate (301, 303) on both sides; A rotating shaft 330 provided inside the accommodating part 310 in a state where both ends thereof are axially coupled to one side and the other side plates 301 and 303 of the accommodating part 310; The rotary shaft 330 is provided on the outer periphery of the rotary shaft 330 at equal intervals, so that the solid biomass fuel 11 accommodated in the accommodation portion 310 can be quantitatively supplied into the transfer pipe 500. It is configured to include; rotates along the rotation blade 350 for quantitatively supplying the solid biomass fuel 11 accommodated in the interior of the receiving portion 310 in the downward direction, The compressed air discharge holes 311 and 313 connected to the compressed air inlet part 530 are formed on the one side and the other side plates 301 and 303, respectively. Scrapers 305 and 307 are formed on one side of the upper side of the rotating blade 350 and the other side of the lower side and extending in the inner circumferential direction of the receiving plate 310 and the other side plates 301 and 303, respectively. One side of the receiving portion 310 and the inner peripheral surface of the other side plate (301, 303) is perpendicularly formed, A detection sensor 320 provided on an inner circumferential surface of the inlet 315 formed above the accommodating part 310 to sense a solid biomass fuel 11 accommodated at a predetermined height inside the accommodating part 310; A drive motor 340 axially coupled with the rotation shaft 330 to forward and reverse rotation of the rotation shaft 330 a predetermined number of times; A control unit is provided to control the driving motor 340 so that the driving motor 340 rotates the rotating shaft 330 forward and backward at a predetermined number of times according to the signal output from the detection sensor 320. The foreign substance which discharges the foreign substance 15 which is heavier than the solid biomass fuel 11 included in the solid biomass fuel 11 in the lower direction so as to communicate with the transfer tube 500 in the downward direction. Rotary feeder device for a biomass combustion system, characterized in that the discharge pipe 550 is vertically provided. delete delete delete delete

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