KR101794692B1 - A quantitative feeder for SRF - Google Patents

Abstract

The present invention relates to a quantitative domestic SRF supply apparatus of an incinerator for cogeneration with urban waste resources and composite fuel. According to the present invention, the quantitative domestic SRF supply apparatus comprises: a blowing fan on an entrance of a case with a passage; an inlet, into which domestic SRF flows, to communicate with a passage on a top surface of the case; and a vane, which controls an opening volume of the passage, with a vane shaft which rotates in the opposite direction by a rotating means to penetrate the case. The present invention is able to control the strength of wind of the blowing fan passing through the vane and the volume of domestic wastes put into the incinerator, thereby burning as much domestic SRF as possible supplied to the incinerator. In addition, the domestic SRF supplied to the passage is supplied by scattering to the inside of the incinerator by wind supplied by the blowing fan, and the present invention is able to improve combustion efficiency.

Description

{A quantitative feeder for SRF} for the life cycle of an incinerator for an urban municipal waste mixed fuel-

[0001] The present invention relates to a life-quantity SRF feeder for an incinerator for combined use of municipal waste and resource-related mixed fuel, and more particularly, to a feeding device having a passage, And the vane for controlling the opening amount of the passage is connected to the vane shaft passing through the case while being rotated in opposite directions to each other by the rotating means, The SRF of the living system supplied to the incinerator can be combusted in a desired amount by controlling the intensity of the wind of the blowing fan discharged to the discharge port to control the amount of the household waste introduced into the incinerator, Since the air supplied from the blower fan or the combustion air is supplied to the interior of the incinerator while being scattered, And the inlet port is provided with a moving pipe that flows into the passageway according to the angle of rotation of the vane and the exit of the moving pipe is located close to the upper side of the air passageway reduced by the rotation angle of the vane The present invention relates to an SRF supply system for a life science SRF for an incinerator for combined use of an urban waste mixed-fuels heat source, in which an SRF supplied through a moving pipe is more smoothly supplied to an incinerator by a venturi effect.

In general, municipal wastes generated in daily life and industrial wastes generated in the workplace are buried or incinerated.

When municipal solid waste or industrial waste is to be buried, landfill costs are increased because a large-scale landfill site must be filled in order to treat a large amount of waste.

Further, after the waste is buried, leachate or the like is generated from the waste, and the leachate or the like flows into the soil or the river to cause contamination of the soil and the river.

In order to solve such a problem, the incinerator is used to incinerate the waste.

In addition, the incinerator of the present invention promotes the use of SRF (solid fuel) in accordance with the government's policy, and due to the increase in calorific value and burning speed due to screening and crushing, the existing incinerator has problems such as refractory litigation And the incinerator of the new combustion type which burns while burning is developed.

The incinerator injects fuel into the combustion chamber to pyrolyze (pyrolyze) combusted waste or fuel in the combustion chamber, and re-burns uncombusted gaseous materials according to combustion conditions or fuel conditions.

The incinerator uses solid waste fuel, which is not only sawdust or wood crumbs but also pelletized waste plastics generated at workplaces or homes, as a fuel. By burning such solid waste fuel to generate heat, boilers and cogeneration And the like have been developed.

Among the fuels, SRF (Solid Refuse Fuel) has higher calorific value and lower price than anthracite coal, making it an alternative fuel for both industrial and public institutions and heating fuel.

1 shows a cogeneration system in which a conventional incinerator is installed.

2. Description of the Related Art Conventional cogeneration includes an incinerator 200, a fuel supply device 210 for supplying a living system SRF to the inside of the incinerator 200, a waste heat recovery device 200 for recovering waste heat generated in the incinerator 200, A waste heat recovery device 220 and a discharge conveyor 230 installed at the lower portion of the incinerator 200 so as to move the scatterer generated during the incineration of the life cycle SRF to a predetermined place.

At least two or more burners for burning waste are installed in the incinerator 200 constructed as described above.

Inside the lower part of the incinerator 200, a grate for moving the waste stepwise is installed.

Therefore, the life science SRF supplied from the fuel supply device 210 is injected into the incinerator 200 and burned. The heat generated in the burning process is exchanged through the waste heat recovery device 220, Is discharged to the discharge conveyor 230 in a collected state.

At this time, the fuel supply device 210 is connected to the incinerator 200 through a supply pipe.

However, when the living system SRF supplied to the combustion chamber of the conventional incinerator 200 is supplied with less than the set fuel amount, the combustion efficiency is lowered, and the equipment is run down due to low air ratio operation.

On the contrary, when SRF is supplied to the SRF more than the set amount of heat, cracks are generated in the incinerator due to the high temperature generated in the combustion furnace, or the burner device is damaged.

When the living system SRF is supplied to the combustion chamber through the fuel supply device 210 in excess of the set fuel amount, the supply pipe connecting the incinerator 200 and the fuel supply device 210 is blocked and the fuel supply device 210 is overloaded Which causes the problem that the cogeneration incineration must be stopped.

In order to solve such a problem, a fuel supplier capable of supplying a living system SRF by a predetermined amount as in the prior patent No. 10-1605194 has been invented.

The conventional fuel supplier includes a transfer tube, a hopper installed on the transfer tube, a horizontal cylinder having a horizontal rod installed to be able to move back and forth in the transfer tube, And a pressing portion for pressing the living system SRF.

Therefore, the living system SRF supplied to the inside of the conveyance pipe through the hopper is supplied to the inside of the combustion chamber of the incinerator while being moved to the outlet of the conveyance pipe due to the operation of the horizontal cylinder.

At this time, the pressurizing portion is pressurized by the living system SRF introduced into the hopper to be smaller than the diameter of the conveying pipe, thereby making it possible to smoothly move the living crab SRF.

However, the problem of the conventional SRF quantity supply device of the incinerator is that the life SRF is supplied to the combustion chamber of the incinerator through the horizontal cylinder while being pressurized by the pressurizing portion, so that the set SRF can not be supplied to the combustion chamber of the incinerator .

Further, since the conventional life-like SRF is supplied to the combustion chamber of the incinerator in a state of being pressurized by the pressurizing portion, the combustion efficiency is lowered.

That is, conventionally, since the life SRF supplied to the incinerator combustion chamber is agglomerated by the pressurizing portion, not only the combustion efficiency is lowered, but also a problem that a predetermined amount of the SRF can not be supplied to the combustion chamber of the incinerator.

In order to solve the above-described problems, the present invention is characterized in that a blowing fan is installed in a charging device provided with a passage, an inlet port through which a living system SRF is introduced is formed on the upper surface of the case so as to communicate with the passage, And the vanes are connected to the vane shaft passing through the case while being rotated in opposite directions to each other by the rotating means. Therefore, the wind intensity of the blowing fan, which is discharged to the discharge port through the passage, The life SRF supplied to the incinerator can be burned to a desired amount, and the life SRF supplied through the passage is dispersed into the incinerator by the air supplied from the blower fan or the combustion air, It is possible to improve the combustion efficiency, and at the inlet, the angle of rotation of the vane The outlet of the moving pipe is located close to the upper side of the air passage reduced by the rotation angle of the vane, and the SRF supplied through the moving pipe by the venturi effect is more smoothly discharged to the incinerator And to provide a living system SRF quantitative supply device for an incinerator for combined use of municipal waste, mixed-fuel, and thermal power.

According to an aspect of the present invention,

A case having a passage formed with an inlet and an outlet;

An inlet formed in the upper portion of the outer circumferential surface of the case so as to communicate with the passageway and introducing a living system SRF (Solid Refuse Fuel) into the case;

A blowing fan installed at an inlet of the case so that the living system SRF flowing into the passage through the inlet port can be vortexed and supplied to the incinerator through the outlet;

A pair of vane shafts installed to penetrate the case close to the inlet;

Rotating means for rotating the vane axes in opposite directions to each other;

And a vane coupled to the outer circumferential surface of the vane shaft so as to adjust wind intensity of the blowing fan discharged through the outlet by adjusting the amount of opening of the passageway and using a vane for controlling the amount of passage opening, And to control the amount of supplied SRF waste in the living system.

According to the present invention, a ventilation fan is installed in a case entrance provided with a passage, an inlet port through which a living system SRF is introduced is formed on the upper surface of the case so as to communicate with the passage, So that the intensity of the wind blown through the passage through the passage is adjusted to adjust the wind intensity to be applied to the incineration furnace, It is possible to expect the effect of burning life SRF supplied to the incinerator as much as possible.

In addition, since the living system SRF supplied to the passage is supplied while being scattered into the incinerator by the wind supplied from the blower fan, the combustion efficiency can be improved.

The inlet port is provided with a moving pipe that flows into the passageway according to the angle of rotation of the vane. The outlet of the moving pipe is positioned close to the upper side of the air passage reduced by the rotation angle of the vane. It is expected that the SRF supplied through the furnace can be smoothly supplied to the incinerator.

Brief Description of the Drawings Fig. 1 is a view showing cogeneration of a conventional life SRF.
BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to an incinerator,
3 is a view showing a constant amount supply device of the SRF of the present invention.
4 shows the rotating means of the invention.
5 is a sectional view showing a state where a vane is installed in the rotating means of the present invention.
FIG. 6 and FIG. 7 are sectional views showing an operating state of the constant amount supply device of the SRF of the present invention. FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to FIGS. 2 to 7 as follows

Prior to the description of the present invention, the same reference numerals are used for the same components as those of the prior art, and the description of the same reference numerals will be omitted.

According to this figure,

A case 10 having a passage 10a provided with an inlet 11 and an outlet 12;

An inlet 13 formed in the upper portion of the outer circumferential surface of the case 10 so as to communicate with the passage 10a and introducing a living SRF (Solid Refuse Fuel) into the case 10;

A blowing fan 110 installed in the inlet 11 of the case 10 so that the living system SRF flowing into the passage 10a through the inlet 13 can be vortexed and supplied to the incinerator 200 through the outlet 12, ;

A pair of vane shafts 20 installed to penetrate the case 10 in proximity to the inlet 11;

Rotating means for rotating the vane shaft 20 in directions opposite to each other;

A vane 30 or 30a connected to the outer circumferential surface of the vane shaft 20 so as to adjust wind intensity of the blowing fan 110 discharged through the outlet 12 by adjusting the amount of opening of the passage 10a, And the amount of life SRF garbage supplied to the incinerator 200 through the discharge port 12 can be controlled by using vanes 30 and 30a for controlling the amount of opening of the passage 10a. do.

The rotating means for rotating the vane shafts 30 in opposite directions are arranged as shown in Fig. 2

A wheel 50 provided with a screw rod 51 and rotatably mounted on a pair of brackets 40 provided on an outer circumferential surface of the case 10;

A moving body (60) having a pin (70) in the middle and screwed to the screw rod (51);

A guide plate (not shown) is provided between the brackets 40 so as to penetrate the end of the pin 70 and allows movement of the moving body 60 in the direction of the inlet 11 and the outlet 12 in accordance with the direction in which the wheel 50 is rotated 71);

The other end of the vane shaft 20 is connected to the vane shaft 20 and the other end thereof is inserted into the pin 70 to be coupled with the vane shaft 20 to convert the linear motion of the moving body 60 into rotational motion, And a connecting link (80) rotating in the opposite direction.

And a rectangular guide hole 72 for allowing the movement of the pin 70 is further formed in the middle of the guide plate 71.

A fixing pipe (90) protruding from the outer surface of the case (10) and coupled to an outer circumferential surface of the inlet (13);

A moving pipe 100 fixed to the inner surface of the fixing pipe 90 by a fixing bolt 92 and being moved inwardly and outwardly of the case 10 through the inlet 13 by an angle of rotation of the vane 30; Configure the installation,

The end (101) of the moving tube (100)

And is connected to the fixing pipe (90) so as to move inward and outward of the case (10) through the inlet (13) so as to be close to the end (31) of the rotated vane (30).

The present invention is a fuel supply device connected to an incinerator 200 and a supply pipe so as to supply a living system SRF supplied to a combustion chamber of the incinerator 200 by a predetermined amount as shown in FIG.

2, a hopper 120 through which the life-style SRF is introduced is spaced apart from the upper surface of the case 10 of the fuel supply device, and a rotation force of the motor is received between the case 10 and the hopper 120, A moving unit 130 having a moving screw 131 installed therein is coupled to the living body SRF so as to supply the living system SRF to the inside of the case 10.

Therefore, in the living system SRF, the living system SRF is supplied to the passage 10a of the case 10 through the inlet 13 as the moving screw 131 provided in the moving unit 130 rotates.

The living system SRF moved to the passage 10a of the case 10 is supplied to the incinerator 200 while being vortexed by the wind supplied from the blowing fan 110 installed at the entrance of the case 10,

The vanes 30 and 30a which are provided inside the case 10 and control the amount of opening of the passage 10a control the intensity of the wind discharged through the discharge port 12, ), The SRF of the living system is introduced.

The vanes 30 and 30a for adjusting the amount of opening of the passage 10a are installed on the outer circumferential surface of the vane shaft 20 as shown in Figures 3 to 7, The vane shafts 20 are rotated in opposite directions to each other by the rotating means so that the amount of opening of the passage 10a provided in the case 10 can be adjusted.

At this time, a moving pipe 100, which can move into the passage 10a of the case 10, is further installed on the inlet 13 provided in the case 10 by an angle of rotation of the vanes 30 and 30a, The living system SRF passing through the moving pipe 100 is sucked by the venturi effect when the strong wind is passed through the passage 10a with the outlet of the moving pipe 100 being close to the passage 10a which is reduced or expanded by the vane So that it can be supplied to the incinerator through the discharge port 12 smoothly.

The moving tube 100 is coupled to the inner surface of the fixing pipe 90 protruding from the outer circumferential surface of the inlet 13 so as to move upward and downward.

At least two bolt holes 91 are formed in the fixing pipe 90 to move the moving pipe 100 upward and downward while the moving pipe 100 is fixed to the inner surface of the fixing pipe 90, As shown in FIG. 6, the fixing bolt 92 is screwed to fix the moving pipe 100 to the fixing pipe 90 or to move up and down.

Therefore, when the vane 30 (30a) is rotated in the inner and outer directions of the case 10, the operator moves the moving tube 100 to the inside and outside of the case 10 by the angle at which the vanes 30 and 30a are rotated The moving tube 100 is positioned so as to be as close as possible to the air passage 10a which is reduced or expanded by the rotation of the vane, so that the venturi effect can be maximized. The SRF can be supplied to the incinerator together with strong wind passing through the passage 10a.

That is, when the vane shaft 20 is rotated by the rotating means and the passage 10a is opened as shown in FIG. 6, the moving tube 100 coupled to the inside of the fixing tube 90 by the fixing bolt 92, The life end SRF can be introduced into the combustion chamber of the incinerator 200 by the venturi effect by moving the upper end 101 of the moving pipe 100 to the upper end of the vane 30, Lt; / RTI &

When the vane shaft 20 is rotated to the center of the case 10 by the rotating means, the ends of the vanes 30 and 30a block a portion of the passage 10a, Since the diameter of the passage 10a is reduced and the operator moves the moving tube 100 to the inside of the passage 10a through the inlet 13 as much as the passage 10a is contracted, The SRF that has passed through the moving pipe 100 by the venturi effect is supplied to the combustion chamber of the incinerator 200 together with the high-speed, high-pressure air passing through the passage 10a .

When the passage 10a is reduced in rotation of the vane, a large amount of SRF is supplied to the incinerator while the air pressure is increased. When the passage 10a is expanded, the air pressure is reduced and a small amount of SRF is supplied to the incinerator.

Therefore, since the amount of the life-series SRF supplied to the combustion chamber of the incinerator 200 is controlled in accordance with the rotation direction of the vanes 30 and 30a and the SRF supplied to the incinerator is supplied while spreading in the incinerator, It is possible to prevent the living system SRF from being incinerated and to prevent the combustion parts installed in the incinerator 200 from being damaged due to an excessive thermal power.

The preferred operating conditions and effects of the present invention will now be described.

3 shows that the moving body 60 screwed to the screw rod 51 of the wheel 50 is moved in the direction of the discharge port 11 by rotating the wheel 50 constituting the rotating means .

As the moving body 60 is moved toward the discharge port 12, the vanes 30 and 30a coupled to the vane shaft 20 are rotated in the outer direction of the case 10, Lt; / RTI >

The movable tube 100 is moved outwardly of the case 10 by releasing the fixing bolt 92 coupled to the fixed tube 90 so that the end 101 of the moving tube 100 is moved to the end 101 of the vane 30, As shown in FIG.

When the vanes 30 and 30a and the moving tube 100 are moved outwardly of the case 10, the wind blowing fan 110 installed at the inlet 11 is operated to supply air to the passage 10a, So that the living system SRF can be introduced through the network 100.

Therefore, even if the wind of the blowing fan 110 passing through the vanes 30 and 30a passes through the portion A of the passage 10a, the flow rate of the air is relatively low, so that a relatively small amount of the life SRF is introduced into the combustion chamber of the incinerator 200 It is possible to supply.

On the other hand, the wheel 50 provided with the screw rod 51 constituting the rotating means is rotated in one direction as shown in Fig. 3 (a) to move the moving body 60 ) In the direction of the inlet (11) of the case (10).

Since the pin 70 provided in the moving body 60 passes through the guide hole 72 provided in the guide plate 71 provided between the brackets 40 as shown in FIG. 4, the screw rod 51 is screwed The moving body 60 is moved to the inlet 11 of the case 10 in a straight line without rotating in the direction in which the screw rod 51 is rotated.

7, the connecting link 80 connected to the pin 70 moves the vane shaft 20 coupled with the vanes 30 and 30a to move the moving body 60 in the inlet direction of the case 10, So that the vanes 30 and 30a block part of the passage 10a as shown in FIG. 3 (b).

When the passage 10a is closed by cutting off a portion of the passage 10a of the vane 30 or 30a, the worker releases the fixing bolt 92 screwed to the fixing pipe 90, 7 so that the end 31 of the vane 30 and the end 101 of the moving tube 100 come close to each other as shown in FIG.

When the end 31 of the vane 30 approaches the end 101 of the moving pipe 100, the wind blowing fan 110 installed at the inlet 11 of the case 10 is actuated to wind the passage 10a Supply.

The wind supplied to the passage 10a is discharged to the discharge port 12 along one side of the opposite vanes 30 and 30a,

The wind which is discharged to the discharge port 12 flows into the casing 10 through the vane 30 and the inflow pipe 100 flowing into the case 10, You can pass at speed.

Therefore, a large amount of life SRF flowing into the case 10 through the moving pipe 100 is supplied to the combustion chamber of the incinerator 200 together with high-speed, high-pressure air passing through the passage 10a.

Since the opening amount of the passage 10a provided in the case 10 is controlled while the vanes 30 and 30a provided in the vane shaft 20 are rotated inward and outward of the case 10, 200 can be controlled by controlling the amount of SRF supplied to the combustion chamber.

The living system SRF supplied to the inside of the case 10 is supplied to the combustion chamber of the incinerator 200 while being vortexed by the wind supplied from the ventilation fan 100. The living system SRF flowing into the incinerator 200 is supplied to the incinerator 200 ) Is scattered in the combustion chamber, the effect of maximizing the combustion efficiency can be expected.

The moving pipe 100 is installed to move upward and downward on the upper surface of the case 10 in the vicinity of the discharge port 12. The moving distance of the moving pipe 100 is set to be the same as that of the vane 30, It is possible to expect the effect that the SRF can be smoothly supplied to the incinerator by maximizing the venturi effect by being moved by the rotated distance.

10: case, 10a: passage,
11: inlet, 12: outlet,
13: inlet, 20: vane axis,
30,30a: Vane, 31: End,
40: Bracket, 50: Wheel,
51: screw rod, 60: moving tube,
70: pin, 71: guide plate,
72: guide hole, 80: connecting link,
90: fixed pipe, 91: bolt hole,
92: Fixing bolt, 100: Moving tube,
101: end, 110: blowing fan,
120: hopper, 130: moving part,
100: moving pipe, 110: blowing fan,
120: hopper, 130: moving part,
131: moving screw,

Claims (4)

A case 10 having a passage 10a provided with an inlet 11 and an outlet 12;
An inlet 13 formed in the upper portion of the outer circumferential surface of the case 10 so as to communicate with the passage 10a and introducing a living SRF (Solid Refuse Fuel) into the case 10;
A blowing fan 110 installed in the inlet 11 of the case 10 so as to swirl the living system SRF flowing into the passage 10a through the inlet 13 and supply it to the incinerator 200 through the outlet 12; ;
A pair of vane shafts 20 installed to penetrate the case 10 in proximity to the inlet 11;
Rotating means for rotating the vane shaft 20 in directions opposite to each other;
A vane 30 or 30a connected to the outer circumferential surface of the vane shaft 20 so as to adjust wind intensity of the blowing fan 110 discharged through the outlet 12 by adjusting the amount of opening of the passage 10a, And the amount of life SRF garbage supplied to the incinerator 200 through the discharge port 12 can be controlled by using vanes 30 and 30a for controlling the amount of opening of the passage 10a. The SRF quantitative supply system in the life sciences of incinerators for urban combined waste fuel combined heat and power generation.
The apparatus according to claim 1,
A wheel 50 provided with a screw rod 51 and rotatably mounted on a pair of brackets 40 provided on an outer circumferential surface of the case 10;
A moving body (60) having a pin (70) in the middle and screwed to the screw rod (51);
A guide plate (not shown) is provided between the brackets 40 so as to penetrate the end of the pin 70 and allows movement of the moving body 60 in the direction of the inlet 11 and the outlet 12 in accordance with the direction in which the wheel 50 is rotated 71);
The other end of the vane shaft 20 is connected to the vane shaft 20 and the other end thereof is inserted into the pin 70 to be coupled with the vane shaft 20 to convert linear motion of the moving body 60 into rotational motion, And a connection link (80) for rotating the rotary kiln in the opposite direction.
The method according to claim 2,
Wherein a rectangular guide hole (72) for allowing the movement of the pin (70) is further formed in the middle of the guide plate (71).
The method according to claim 1,
A fixing pipe (90) protruding from the outer surface of the case (10) and coupled to the outer circumferential surface of the inlet (13);
A moving pipe 100 fixed to the inner surface of the fixing pipe 90 by a fixing bolt 92 and being moved inwardly and outwardly of the case 10 through the inlet 13 by an angle of rotation of the vane 30; Configure the installation,
The end (101) of the moving tube (100)
Is connected to the fixed pipe (90) so as to move in the inward and outward directions of the case (10) through the inlet (13) so as to approach the end (31) of the rotated vane (30) SRF Quantity Feeding System in the Life Sector of Combined Incinerator.

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