KR100743219B1 - Sludge insert device for incinerator - Google Patents

Abstract

A sludge inserting device for an incinerator is provided to rapidly burn minutely pulverized sludge cakes inputted into the incinerator with less fuel consumption. A sludge inserting device for an incinerator includes a hopper(11), a sludge transferring pipe unit(13), a transferring screw(21), a screw rotating motor, a sludge dividing piece(25), a rotating cutter(27), and a cutter rotating motor. The hopper receives compressed sludge. The sludge transferring pipe unit is formed from the hopper to the incinerator. The transferring screw is rotatably installed inside the sludge transferring pipe unit. The screw rotating motor rotates the transferring screw. The sludge dividing piece is placed at an end of the incinerator side of the sludge transferring pipe unit. The rotating cutter is installed to rotate at higher speed than the transferring screw at a front area of the sludge dividing piece. The cutter rotating motor rotates the rotating cutter.

Description

Incinerator sludge injector {Sludge insert device for incinerator}

1 is a side cross-sectional view of an incinerator sludge injector according to the present invention;

Figure 2 is a cross-sectional plan view of the incinerator sludge injector of Figure 1,

3 is an enlarged perspective view of the sludge-divided piece region of FIGS. 1 and 2;

4 is a side cross-sectional view of a conventional incinerator sludge injector,

5 is an enlarged perspective view of the sludge-divided piece region of FIG.

* Explanation of symbols for the main parts of the drawings

11: hopper 13: sludge transport pipe

21: feed screw 23: screw rotation motor

25: sludge fractionation 27: rotary cutter

29: cutter rotation motor 31: compressed air supply

33: compressed air flow path

The present invention relates to an incinerator sludge injector, and more particularly, to an incinerator sludge injector capable of reducing fuel consumption of an incinerator and increasing sludge combustion throughput.

The sludge discharged from the waste water treatment facility is removed from the dehydrator as much as possible, and then compressed in a press. The compressed sludge (hereinafter referred to as "compressed sludge") is put into an incinerator and incinerated. At this time, the compressed sludge is crushed to an appropriate volume while passing through an incinerator sludge injector for smooth incineration, and then injected into an incinerator.

4 is a side cross-sectional view of a conventional incinerator sludge injector. As shown in this figure, the conventional incinerator sludge injector 101 receives the compressed sludge generated in the waste water treatment facility in the hopper 110, the compressed sludge received in the hopper 110 in the lower portion of the hopper 110. The sludge feed crushing means 120 is transferred to the incinerator 105 while being crushed into a predetermined size and introduced into the incinerator 105.

Here, the sludge conveying pulverization means 120 is a feed screw 123 rotatably installed in the sludge conveying pipe portion 113 formed toward the incinerator 105 from the bottom of the hopper 110, and the incinerator of the sludge conveying pipe portion 113 ( 105) The sludge split piece 121 installed in the feed end region, the rotary cutter 125 coupled to the rotary shaft end region of the feed screw 123 in the feed region of the incinerator 105, and the drive motor for rotating the feed screw 123. It includes (129).

In the conventional incinerator sludge injector 101 having such a configuration, when the feed screw 123 is rotated by the driving of the drive motor 129, the compressed sludge received at the hopper 110 is transferred through the sludge feed pipe part 113 to the feed screw ( 123 is transferred to the incinerator 105 side.

Then, the compressed sludge to be fed is supplied into the incinerator 105 while being divided into a plurality by the sludge split piece 121 at the inlet end side of the incinerator 105 side of the sludge conveying pipe 113, the divided compressed sludge is a conveying screw 123 is cut into the sludge cake (A) by the number of divided by the rotary cutter 125 to rotate with the feed screw 123 at the end of the rotary shaft is introduced into the incinerator 105. As a result, the compressed sludge can be introduced into the incinerator 105 while the cut sludge is cut into a predetermined size.

However, in the conventional incinerator sludge feeder, since the rotational speed of the conveying screw can only be reduced by the pressure of the compressed sludge, the rotary cutter which rotates integrally with the conveying screw also rotates only at a low speed.

Therefore, when the compressed sludge conveyed toward the incinerator along the conveying screw is divided in the sludge splitting piece and then cut by the rotary cutter, as shown in FIG. 5, the volume of the cut sludge cake A is relatively small. It is largely formed.

When the volume of sludge cake is largely formed and supplied to the incinerator, the time for burning the sludge cake having a large volume increases, and thus, the fuel consumption of the incinerator for combustion of the sludge cake increases.

In addition, when the combustion time of the sludge cake increases, the amount of sludge cake to be injected into the incinerator needs to be limited, and thus a sludge combustion throughput cannot be increased.

It is therefore an object of the present invention to provide an incinerator sludge injector capable of increasing the sludge combustion throughput while reducing fuel consumption and combustion time of the incinerator.

According to the present invention, in the incinerator sludge injector, a hopper for receiving the compressed sludge, a sludge conveying pipe portion from the hopper to the incinerator, a rotating screw installed in the sludge conveying pipe portion, the rotating screw is rotated A screw rotating motor to be installed, a sludge split piece provided in the incinerator side end region of the sludge conveying pipe part, a rotary cutter installed to rotate at a higher speed than the feed screw in the front region of the sludge split piece, and a cutter rotating motor to rotate the rotary cutter. It is achieved by an incinerator sludge injector characterized in that it has a.

Here, the feed screw has a hollow screw rotating shaft, and a screw blade formed spirally along the longitudinal direction on the outer peripheral surface of the screw rotating shaft; The rotary cutter preferably has a cutter shaft rotatably installed in the screw rotation shaft and a cutter blade coupled to the cutter shaft in front of the sludge split piece.

In addition, it is effective that the sludge split piece is formed by at least eight split pieces radially arranged in the inlet end region on the incinerator side of the sludge conveying pipe part.

At this time, the rotation speed of the feed screw is 12 RPM to 13 RPM, the rotation speed of the rotary cutter is more preferably 400 to 600 RPM.

In addition, the compressed air supply for generating compressed air, the compressed air flow path is formed toward the incinerator input area from the compressed air supply, and the compressed air injection for injecting the compressed air supplied through the compressed air flow path to the front of the cutter blade It is more effective to further include sludge grinding means having a nozzle.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention.

1 is a side cross-sectional view of an incinerator sludge injector according to the present invention, and FIG. 2 is a plan cross-sectional view of the incinerator sludge injector shown in FIG. 1. As shown in these drawings, the incinerator sludge injector 1 according to the present invention includes a sludge hopper 10 and a sludge hopper 10 which form a receiving space for the compressed sludge and a transport space for the incinerator 5. A sludge conveyance dividing means 20 for moving the compressed sludge to an incinerator 5, dividing the compressed sludge into a predetermined size, and feeding the compressed sludge into the incinerator 5; and a sludge crushing means 30 for finely crushing the divided compressed sludge. .

The sludge hopper 10 has a hopper 11 which receives compressed sludge from a wastewater treatment facility, and a sludge conveying pipe part 13 which forms a compressed sludge moving path from the hopper 11 toward the incinerator 5. The upper part of the hopper 11 is formed with a sludge inlet 15 through which compressed sludge can be introduced, and the lower region of the hopper 11 communicates with the sludge conveying pipe part 13. At this time, the inner wall of the hopper 11 is preferably formed to be inclined downward so that the compressed sludge falls smoothly into the sludge conveying pipe portion 13 by its own weight.

The sludge conveyance dividing means 20 is a screw rotating motor for rotating the conveying screw 21 and the conveying screw 21 for conveying the compressed sludge accommodated in the hopper 11 to the incinerator 5 through the sludge conveying pipe part 13. (23), a sludge dividing piece (25) for dividing a plurality of compressed sludges in the inlet end region of the incinerator (5) side of the sludge conveying pipe section (13), a rotary cutter (27) for cutting the divided sludges, and rotation It has the cutter rotation motor 29 which rotates the cutter 27. As shown in FIG.

The conveying screw 21 has a structure in which a hollow screw rotating shaft 21a and a screw blade 21b formed in a spiral shape along the longitudinal direction are integrally formed on the outer circumferential surface of the screw rotating shaft 21a. The conveying screw 21 is installed so that the screw rotation shaft 21a receives a driving force from the screw rotation motor 23 by a belt pulley or a chain, and rotates in accordance with the driving of the screw rotation motor 23 to incinerate the compressed sludge ( Transfer to 5).

The screw rotation motor 23 is installed adjacent to the screw rotation shaft 21a in the rear region of the sludge hopper 10 and is connected to the screw rotation shaft 21a by a belt pulley or a chain. The screw rotation motor 23 rotates the feed screw 21 at a relatively low speed in consideration of the pressure of the compressed sludge and the like. At this time, the rotational speed of the transfer screw 21 is preferably 12 RPM to 13 RPM.

The sludge dividing piece 25 is formed by a plurality of split pieces 25a radially arranged in the inlet end region on the incinerator 5 side of the sludge conveying pipe part 13. At the center of the divided pieces 25a, a screw journal portion 25b for rotatably supporting the screw rotating shaft 21a of the feed screw 21 is provided. Here, it is preferable that at least eight divided pieces 25a are provided under conditions in which compressed sludge is smoothly discharged while minimizing the volume of the sludge cake a.

The rotary cutter 27 is a cutter shaft 27a that is rotatably installed in the screw rotation shaft 21a of the feed screw 21, and the cutter shaft 27a in front of the sludge split piece 25 in the incinerator 5 inside. It includes a cutter blade (27b) coupled to). The rotary cutter 27 is rotated separately from the feed screw 21 by the independent rotation of the cutter shaft (27a). To this end, the rear end of the cutter shaft 27a is connected to the cutter rotating motor 29 and the belt pulley or chain so as to receive the driving force from the cutter rotating motor 29.

The cutter rotating motor 29 is installed adjacent to the cutter shaft 27a in the rear region of the sludge hopper 10 and is connected to the cutter shaft 27a by a belt pulley or a chain. The cutter rotary motor 29 rotates the rotary cutter 27 at a higher speed than the feed screw 21 so that the compressed sludge divided in the sludge splitting piece 25 can be cut into a sludge cake a having a relatively small volume. Let's do it. Here, the rotation speed of the rotary cutter 27 is preferably 400 RPM to 600 RPM.

On the other hand, the sludge crushing means 30 is a compressed air supply 31 for supplying compressed air, a compressed air flow path 33 formed from the compressed air supply 31 toward the incinerator 5 input region, and a compressed air flow path Compressed air supplied through the (33) is composed of a compressed air injection nozzle 35 for spraying the sludge cake (a) cut cut.

The compressed air supplier 31 is provided as an air compressor and installed in the rear region of the sludge hopper 10. The compressed air flow path 33 is provided with a cutter shaft 27a of the rotary cutter 27 in the form of a hollow tube. Its interior can be used as a compressed air flow path 33 is connected to the compressed air supply (31). In addition, the compressed air injection nozzle 35 may be provided in the form of a nozzle hole on the cutter blade 27b facing the incinerator 5 side to be connected to the compressed air flow path 33 of the cutter shaft 27a.

By this configuration, it looks at the operation of the incinerator sludge injector 1 according to the present invention.

When the feed screw 21 rotates at a low speed by driving the screw rotating motor 23, the compressed sludge received by the hopper 11 is transferred to the incinerator 5 side along the feed screw 21 through the sludge feed pipe 13. do. Then, by the driving of the cutter rotating motor 29, the rotary cutter 27 rotates independently of the feed screw 21 at a high speed.

The compressed sludge conveyed by the conveying screw 21 is supplied into the incinerator 5 while being divided into a plurality of sludge split pieces 25, and the divided compressed sludge is divided by the rotating cutter 27 rotating at a high speed. As many sludge cakes (a) are cut into the incinerator (5). At this time, the rotary cutter 27 that rotates at a high speed is divided at a low speed to quickly cut the compressed sludge supplied to the incinerator 5, thereby minimizing the volume of the sludge cake a.

On the other hand, the sludge grinding means 30 is a sludge cake while the compressed air supplied from the compressed air supply (31) is injected into the sludge cake (a) through the compressed air passage 33 through the nozzle hole of the cutter blade (27b) (a) Finely grind. As a result, as shown in FIG. 3, the small volume sludge cake a is finely pulverized and introduced into the incinerator 5.

As described above, the incinerator sludge feeder according to the present invention rotates the feed screw at a low speed and rotates the rotary cutter at a high speed, so that the sludge cake is finely divided by the sludge grinding means while simultaneously cutting and cutting the compressed sludge into a small sludge cake. It can be crushed and put into an incinerator.

As a result, the finely ground sludge cake introduced into the incinerator is not only burned in a short time but also burns the sludge cake ground in a small amount of fuel in the incinerator.

Therefore, it is possible to significantly reduce the combustion time and incinerator fuel consumption of the sludge cake and increase the sludge combustion throughput.

As described above, according to the present invention, an incinerator sludge injector capable of reducing the fuel consumption and combustion time of an incinerator and increasing the sludge combustion throughput is provided.

Claims (5)

In the incinerator sludge feeder, Hopper to accommodate compressed sludge, Sludge conveying pipe portion toward the incinerator from the hopper, A conveying screw rotatably installed in the sludge conveying pipe part; Screw rotating motor for rotating the transfer screw, Sludge split piece provided in the incinerator side end region of the sludge feed pipe, A rotary cutter installed to rotate at a higher speed than the transfer screw in the front region of the sludge split piece, Incinerator sludge injector, characterized in that having a cutter rotating motor for rotating the rotary cutter. The method of claim 1, The feed screw has a hollow screw rotating shaft and a screw blade formed spirally along the longitudinal direction on the outer circumferential surface of the screw rotating shaft; The rotary cutter is an incinerator sludge injector, characterized in that it has a cutter shaft rotatably installed in the screw rotation shaft and a cutter blade coupled to the cutter shaft in front of the sludge split piece. The method according to claim 1 or 2, An incinerator sludge injector, characterized in that the sludge split piece is formed by at least eight split pieces radially arranged in the inlet end region of the incinerator side of the sludge feed pipe. The method of claim 1, Incinerator sludge injector, characterized in that the rotation speed of the feed screw is 12 RPM to 13 RPM, the rotation speed of the rotary cutter is 400 RPM to 600 RPM. The method of claim 1, A compressed air supply for generating compressed air, a compressed air flow path formed toward the incinerator input region in the compressed air supply, and a compressed air injection nozzle for spraying the compressed air supplied through the compressed air flow path to the front area of the cutter blade. Incinerator sludge injector further comprising a sludge crushing means having.

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