KR20030083336A - kiln - Google Patents

Abstract

PURPOSE: A drying furnace is provided to improve drying efficiency by preventing steam from being absorbed into sludge again with forcibly discharging steam from the duct, and to transfer sludge actively by restricting lump of sludge with reducing the height of the transfer blade. CONSTITUTION: A drying furnace comprises a screw type sludge supply unit(1); plural drying cylinders(10) composed of inlets(11) formed in the upper part to input sludge from the sludge supply unit and outlets(12) discharging sludge, and stacked in multiple steps; a transfer screw(20) installed in the drying cylinder and rotated to transfer sludge from the inlet to the outlet; and a case(30) surrounding plural drying cylinders, and heating the drying cylinders by receiving high temperature gas from the incinerator. A duct(13) is formed in the upper part of the drying cylinder to collect saturated steam, and connected to an inlet pipe(14) to input hot air from the heat exchanger and a steam recovery pipe(15) to discharge saturated steam. Drying efficiency is improved by forcibly discharging steam from the duct.

Description

Drying furnace {kiln}

The present invention relates to a drying furnace installed in an incineration treatment apparatus, and to a drying furnace for smoothly transporting sludge while efficiently removing moisture contained in sludge.

In general, the sludge incineration treatment apparatus is a device for minimizing the volume of the sludge by incineration after removing the water contained in the sludge obtained from the sewer. In such an incineration treatment apparatus, in order to incinerate sludge efficiently, the drying furnace is removed to remove moisture contained in the sludge, so that energy can be incinerated in a short time. Therefore, the energy consumption of the incineration apparatus is determined according to the performance of the drying furnace installed in the incineration apparatus.

Such a conventional drying furnace and a screw type sludge supply device,

Inlet is formed in the upper side so that the sludge supplied by the sludge supply device is introduced, a discharge port for the sludge is discharged to the bottom of the other end is formed a plurality of dry cylinder laminated in a multi-stage,

A transfer screw for transferring the sludge introduced through the inlet to the outlet as it is installed and rotated inside the drying cylinder;

It surrounds the plurality of drying cylinders, the hot gas discharged from the incinerator is supplied from the bottom is composed of a case for heating the drying cylinder.

However, the conventional drying furnace having the structure as described above has the following problems.

First, water is released from the sludge transported to the drying cylinder, and water vapor is generated in the drying cylinder, and the water vapor is gradually agglomerated to become liquid and absorbed again into the sludge, thereby causing a very low drying rate.

Second, since the transfer cylinder installed inside the drying cylinder to transport the sludge is formed with a wide transfer blade around the thin shaft, a large amount of sludge can be transferred, but there is a problem of being frequently blocked in the drying cylinder. There was a problem that came out.

Third, there is a problem in that the cold sludge supply device does not have a device to thaw when the sludge supply device is frozen, it is impossible to operate.

Accordingly, the present invention has been made to solve the problems described above, it is possible to release the steam generated in the drying cylinder to the outside to close the complete drying while increasing the shaft diameter of the transfer screw installed in the drying cylinder On the other hand, the object of the present invention is to provide a drying furnace that minimizes clogging and agglomeration by reducing the height of the transfer blade.

Drying furnace according to the present invention for achieving the above object is a screw type sludge supply apparatus; A plurality of drying cylinders having an inlet formed at an upper side thereof so that the sludge supplied by the sludge supply device is inputted, and a sludge discharge port at which the sludge is discharged to a lower portion of the other end thereof; A transfer screw installed to rotate inside the drying cylinder and transferring the sludge introduced through the inlet to the outlet as it is rotated; In the drying furnace consisting of a case surrounding the plurality of drying cylinders and receiving a high-temperature gas discharged from the incinerator to heat the drying cylinder,

The drying cylinder has a duct having a space for collecting steam in a saturated state is formed in the upper part of the drying cylinder, the inlet pipe is connected to one end of the duct to allow the high-temperature air from the heat exchanger, the other end is saturated Characterized in that the steam recovery pipe is installed to discharge the steam of.

In addition, the conveying screw is characterized in that to increase the diameter of the rotating shaft, the height of the spiral feed wing is integrally attached to the outer peripheral surface of the rotating shaft.

In addition, the case is formed with a waste gas inlet through which waste gas flows into one side of the case, and a waste gas outlet through which waste gas is discharged from the other end of the case, and forms a vertical bulkhead in which one end is alternately opened to form a high temperature waste gas. The drying cylinder is heated while being zigzag.

In addition, the sludge supply device is formed into a double pipe, characterized in that the hot waste gas passing through the drying furnace flows through the double pipe of the sludge supply device.

1 is a front sectional view showing the structure of a drying furnace according to the present invention;

Figure 2 is a side cross-sectional view showing the structure of a drying furnace according to the present invention,

3 is a perspective view showing a drying cylinder of a drying furnace according to the present invention;

Figure 4 is a cross-sectional view showing a drying cylinder of the drying furnace according to the present invention.

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

1: sludge supply device 10: drying cylinder 11: sludge inlet

12 sludge outlet 13 duct 14 inlet pipe

15: steam recovery pipe 16: discharge pipe 20: transfer screw

21: rotating shaft 22: feed wing 30: case

31: bulkhead 40: moisture sorting tank 41: body

42: wall 50, 60: feed screw

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

1 is a front sectional view showing the structure of a drying furnace according to the present invention, Figure 2 is a side cross-sectional view showing the structure of the drying furnace according to the invention, Figure 3 is a perspective view showing a drying cylinder of the drying furnace according to the invention 4 is a cross-sectional view illustrating a drying cylinder of a drying furnace according to the present invention.

As shown in these drawings, the drying furnace according to the present invention is a screw type sludge supply apparatus 1; Inlet 11 is formed on the upper side so that the sludge supplied by the sludge supply device 1 is introduced, the sludge discharge port 12 is formed to discharge the sludge to the bottom of the other end is a plurality of relay-stacked Two dry cylinders 10; A transfer screw 20 for transferring the sludge introduced through the sludge inlet 11 to the discharge port as it is installed and rotated inside the drying cylinder 10; In the drying furnace composed of a case 30 for wrapping the plurality of drying cylinders 10 and receives the high-temperature gas discharged from the incinerator to heat the drying cylinder 10,

The drying cylinder 10 has a duct 13 having a space for collecting steam in a saturation state is formed in the upper portion of the drying cylinder 10, so that the hot air from the heat exchanger is introduced into one end of the duct 13 To the inlet pipe 14 is connected, the other end of the steam recovery pipe 15 for discharging the steam in a saturated state is installed.

Here, the inlet pipes 14 are distributed from the inlet pipe installed vertically to the outside of the drying furnace and connected to each drying cylinder 10 duct 13, and the water vapor recovery pipes 15 on the other side are also outside the drying furnace. It is connected to the discharge pipe 16 is installed vertically. Accordingly, water vapor generated from the sludge passing through the drying cylinder 10 is collected in the duct 13 formed at the top thereof and simultaneously moved to the discharge pipe 16 by the air flowing from the inlet pipe 14 to the steam recovery pipe 15. do. At this time, the air introduced into the inlet pipe is the air converted to high temperature through the heat exchanger of the incinerator. Then, the air containing the steam is moved to the water sorting tank 40 provided at the end of the discharge pipe (16).

The water sorting tank 40 is formed of a cylindrical body 41, and forms an inlet on one side, and forms a vertical wall 42 at the rear end of the inlet, so that the water condenses as the air collides with the bottom of the tank. To be collected. Then, the air is moved to the cleaning dust collector (not shown in the figure) through the discharge pipe formed in the upper to remove the harmful gas.

On the other hand, the conveying screw 20 to increase the diameter of the rotating shaft 21, and to form a small height of the spiral feed blade 22 is integrally attached to the outer peripheral surface of the rotating shaft 21 by the sludge of the drying cylinder 10 It is transported in a thin unfolded state as if spread on the outer wall. Therefore, the sludge dries quickly and the sludge is smoothly transported without clogging because the amount of sludge to be transported is small.

In addition, a waste gas inlet 31 through which waste gas is introduced is formed at one upper side of the case 30, and a waste gas outlet 32 through which waste gas is discharged is formed at the other end of the case 30. A vertical bulkhead 33 is formed in the case 30, and the bulkhead 33 alternately has openings formed in upper and lower parts thereof, so that hot waste gas moves in a zigzag, and thus, the drying cylinder 10. The heat is transferred evenly.

In addition, the lower part of the case 30 is inclined so that heavy dust contained in the waste gas is collected downward along the inclined surface, and a transfer screw 50 is installed at an inclined end to selectively discharge the sunk dust. Make sure

Through the drying furnace made of such a structure is discharged to the incinerator through the transport screw (60) installed at the bottom, the discharged sludge is very low and when inflow into the incinerator is incinerated in a short time, so the energy consumption of the incinerator is less It is lifting.

In addition, the sludge supply apparatus 1 has an outer wall formed of a double pipe, a gas inlet is formed at one end thereof, and a gas outlet is formed at the other end thereof, so that the hot waste gas passed through the case inside the drying furnace is supplied with sludge. The sludge feeder 1 does not freeze in cold weather by being connected to the gas inlet of the device 1.

In this way, the waste gas passing through the sludge supply device 1 does not need to pass through a separate cooling device since the temperature drops sharply, and is immediately moved to the bag filter dust collector to remove dust contained in the gas.

As described above, the drying furnace according to the present invention has the following effects.

First, the drying furnace according to the present invention is provided with a duct capable of collecting water vapor in the upper part of the drying cylinder, and by forcibly discharging the water vapor collected in the duct, the phenomenon that the water vapor is liquefied to be reabsorbed in the sludge, the drying efficiency is increased It works.

Secondly, the drying furnace according to the present invention has a small height of the conveying screw feed wing is formed so that the sludge is spread thinly spread on the inner surface of the drying cylinder and is quickly dried, the agglomeration of the sludge disappears as well as the sludge is smoothly transferred.

Third, the drying furnace according to the present invention has the effect that the high-temperature gas is evenly distributed by the partition wall formed inside the case to heat the entire cladding cylinder.

Fourth, the drying furnace according to the present invention by supplying the hot waste gas passing through the case of the drying furnace to the double pipe of the sludge supply apparatus, not only does the sludge supply apparatus not freeze even in cold weather, but also the waste gas passed through the sludge supply apparatus is rapidly dropped in temperature. Since it moves directly to the bag filter dust collector without going through a separate cooling device, there is no need to go through the cooling device has the effect of saving the construction cost.

Claims (5)

A plurality of drying cylinders in which an inlet for injecting sludge is formed at an upper side thereof, and an outlet for discharging sludge is formed at a lower portion of the other end thereof, and stacked in multiple stages in a relay manner; A transfer screw installed to rotate inside the drying cylinder and transferring the sludge introduced through the inlet to the outlet as it is rotated; In the drying furnace consisting of a case surrounding the plurality of drying cylinders and receiving a high-temperature gas discharged from the incinerator to heat the drying cylinder, The drying cylinder has a duct having a space for collecting steam in a saturated state is formed in the upper part of the drying cylinder, the inlet pipe is connected to one end of the duct to allow the high-temperature air from the heat exchanger, the other end is saturated Drying furnace characterized in that the steam recovery pipe is installed to discharge the steam of. The drying furnace according to claim 1, wherein the conveying screw increases the diameter of the rotating shaft and reduces the height of the spiral conveying blade which is integrally attached to the outer circumferential surface of the rotating shaft. According to claim 1, wherein the case is formed waste gas inlet for the waste gas flow in the upper one side, the waste gas outlet is formed in the other end of the upper end, the inner side of the case to form a vertical bulkhead opened alternately A drying furnace characterized in that the hot waste gas flows in a zigzag to heat the drying cylinder. The method of claim 3, wherein the lower part of the case is inclined so that heavy dust contained in the waste gas flowing in the air collects downward along the inclined surface, and a transport screw is installed at an inclined end to discharge the sinked dust to the outside. Drying furnace, characterized in that. 2. The drying furnace according to claim 1, wherein the sludge supply device is formed by a double pipe in appearance, and connects the hot waste gas passing through the inside of the case to flow through the double pipe of the sludge supply device.