KR20140124909A - Apparatus for drying sludge - Google Patents

Abstract

The present invention relates to a sludge drying apparatus capable of quickly drying large amounts of sludge as various wastes generated from industrial sites, houses, stables, etc. According to the present invention, a sludge drying apparatus comprises: a horizontal chamber (110); a sludge inlet hopper (120) installed in the front end of the horizontal chamber; a sludge outlet (130) installed in the rear end of the horizontal chamber; a transfer screw (140) installed in the horizontal chamber transferring sludge which flows into the hopper when rotating in one direction; a circulation flow path including a first flow path (152) installed in the horizontal chamber, a second flow path (152) formed along the vane (141) of the transfer screw, and a third flow path (153) of which both ends are connected to the front ends and the rear ends of the first flow path and the second flow path; a heat medium filling the circulation flow path; a heater (170) installed in the third flow path heating the heat medium filling the circulation flow path; and a circulation pump (180) installed in the third flow path providing a circulation force for the heat medium.

Description

[0001] Apparatus for drying sludge [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sludge drying apparatus capable of rapidly drying sludge, which is various wastes generated in an industrial field, a home, a housing, and the like, in a large amount.

Recently, interest in the treatment of water-containing wastes (hereinafter referred to as " sludge ") from various wastes generated in various fields is increasing. Such sludge may include, for example, wastewater sludge from a wastewater treatment facility, humid waste from an industrial site such as a food or paper factory, food waste from a household, and livestock manure from a livestock farm.

Since such sludge usually contains about 80% of water, it is excluded from general incineration facilities and treatment through landfill is generalized. However, the disposal of sludge through landfill has been problematic due to secondary pollution such as groundwater due to leachate, weakening of ground, securing landfill area, and alternative technology is required.

Therefore, many techniques for sludge treatment have been developed to solve the above-mentioned problems. A multi-stage screw dryer of Korean Patent Application Publication No. 2002-0005917 is known as such a patented technology.

In this dryer, a plurality of drying cylinders provided with screws are arranged adjacent to each other, and a drying object injected into the drying cylinder at the uppermost stage is continuously transferred from the upper portion to the lower portion and discharged through the drying cylinder at the lower end, The hot air injected into the drying cylinder continuously flows from the lower part to the upper part and is exhausted through the uppermost drying cylinder.

However, such a conventional technique has a problem in that the drying time is prolonged because of low thermal efficiency.

Further, the sludge transported inside the screw is not influenced by hot air, and thus, the drying can not be normally performed.

If the sludge transferred to the inside of the screw is not dried, another problem that the screw is overloaded is caused.

It is an object of the present invention to provide a sludge drying apparatus capable of rapidly drying sludge transferred to the inside of a screw while smoothly drying the sludge.

In order to achieve the above object, a sludge drying apparatus of the present invention comprises a horizontal chamber, a hopper for introducing sludge installed at a front end of the horizontal chamber, a sludge discharge port provided at a rear end of the horizontal chamber, A first flow path provided in the horizontal chamber, a second flow path formed along the blade of the feed screw, and both ends connected to the first flow path and the second flow path, respectively, A heater which heats the heating medium filled in the circulating flow passage, a heater installed on the third flow passage, and a heater which heats the heating medium which is filled in the circulating flow passage; And a circulation pump installed on the flow path to supply a circulation force to the heating medium.

It is preferable that the second flow path includes a bladed flow path formed inside the blade of the conveying screw and a front and rear rotating shaft flow path formed inside both ends of the rotation axis of the conveyance screw to connect the bladed flow path and the third flow path Do.

In addition, a jacket surrounding the lower and both sides of the horizontal chamber may be provided outside the horizontal chamber, and the first flow path may be an internal space of the jacket.

Since the heating medium is circulated through the second flow path formed along the blade of the conveying screw, the sludge conveyed to the inside of the conveying screw is smoothly dried, and the overall drying speed is also greatly improved have.

1 is a sectional view of a sludge drying apparatus according to the present invention;
2 is a perspective view of a horizontal chamber and a delivery screw constituting the present invention.
3 is a cross-sectional view taken along line III-III in Fig.
4 is a detailed view of "A"
5 is a detailed view of "B"

The features and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It must be interpreted in terms of meaning and concept.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings. The same reference numerals are used for the same components, and only the different portions are described for the sake of clarity.

1, the sludge drying apparatus of the present invention includes a horizontal chamber 110, a sludge inlet hopper 120 installed at a front end of the horizontal chamber 110, And a transfer screw 140 installed in the horizontal chamber 110 and rotating in one direction to transfer the sludge introduced into the hopper 120 to the sludge discharge port 130 .

In the sludge drying apparatus of the present invention, a heating medium heated to a high temperature circulates through the transfer screw 140 and the horizontal chamber 110, and the sludge introduced into the horizontal chamber 110 is heated to a high temperature, Respectively.

The circulation channel is filled with a heating medium (F). Considering that the temperature required for drying the sludge is usually 350 DEG C or higher, water is not suitable as the heat medium and a synthetic heat oil resistant to heat is preferable.

The circulation channel includes a first channel 151 provided in the horizontal chamber 110, a second channel 152 formed along the wing 141 of the conveyance screw 140, 151 and a third flow path 153 connected to the front end and the rear end of the second flow path 152.

2 and 3, the first flow path 151 may be formed by a flow pipe installed along the bottom or bottom of the horizontal chamber 110, It is preferable that the inner space of the jacket 160 installed on the outer side of the horizontal chamber 110 is enclosed.

In this case, the jacket 160 has connecting portions 161 and 162 connected to the third flow path 153 at the front end and the rear end, respectively, and the connecting portions 161 are respectively the front end and the rear end of the first flow path 151 .

Thus, when the first flow path 151 becomes the empty space of the jacket 160, the lower part and the entire side of the horizontal chamber 110 can be raised to a uniform temperature.

The height of the jacket 160 should be designed to an optimum height in consideration of the driving capability of the feed screw 140. This is because when the level of the sludge is higher than the upper end of the jacket 160, the sludge located at the upper end of the jacket 160 is less affected by the heating medium passing through the first flow path 151, If the height of the upper end of the jacket 160 is increased to increase the drying efficiency, the amount of the sludge to be transferred is also increased, so that a large load may be applied to the transfer screw 140.

1, 4 and 5, the second flow path 152 includes a bladed flow path 152a formed in the blade 141 of the feed screw 140, And front and rear rotary shaft flow passages 152b and 152c which are respectively formed at both ends of the rotary shaft 142 to connect the blade flow path 152a and the third flow path 153. [ The wing flow path 152a is a single flow path continuously connected from the front end to the rear end of the feed screw 140. [

The front end of the third flow path 153 is formed so as to be able to connect the front end (connection portion 161) of the first flow path 151 and the front rotation flow path 152b of the second flow path 152 at the same time. The rear end of the third flow path 153 is formed so as to be able to connect the rear end (connection 162) of the first flow path 151 and the rear flow path 152c of the second flow path 152 at the same time.

A heater 170 for heating the heating medium filled in the circulation flow path and a circulation pump 180 for providing the circulation force to the heating medium are installed on the third flow path 153. The circulation pump 180 is arranged in front of the heater 170 in the path of the heating medium.

Accordingly, the heat medium is circulated through the circulation pump 180 and moves along the third flow path 153 in a state of being raised to a high temperature via the heater 170, The first and second flow passages 151 and 152 move along the respective independent paths to the front end of the horizontal chamber 110 and the rear end of the feed screw 140 and are collected at the front end of the third flow path 153, (180). ≪ / RTI >

The reference symbol M is a drive motor for applying a rotational force to the feed screw 140. Although not shown, it is obvious that a speed reducer may be further provided between the driving motor M and the feed screw 140 to rotate the feed screw 140 at a high rotational speed.

An exhaust duct 170 and an exhaust fan 180 are installed in the upper portion of the horizontal chamber 110 to discharge water vapor or fine powder generated in the drying process to the outside. The exhaust duct 170 covers the open top of the horizontal chamber 110 so that the inside of the horizontal chamber 110 is isolated from the outside.

The process of drying the sludge through the sludge drying apparatus having such a structure will be described.

When the circulation pump 180 installed on the third flow path 153 transfers the heating medium to the heater 170, the heating medium flows through the heater 170 in a heated state at a high temperature and flows along the third flow path 153 Move. The heat medium, which is moved to the rear end of the third flow path 153, is branched into the first flow path 151 and the second flow path 152.

The heating medium branched into the first flow path 151 flows into the rear end of the first flow path 151 through the connecting portion 161 formed at the rear end of the jacket 160 to raise the jacket 160 to a high temperature, And then flows into the circulation pump 180 after flowing into the third flow path 153 after being discharged to the front end of the first flow path 151 through the connection part 161 formed at the front end.

The heating medium branched into the second flow path 152 flows into the rear rotary shaft flow path 152c formed in the rear end of the rotary shaft 142 of the feed screw 140 as shown in FIG. . 5, the heating medium passing through the bladed flow path 152a is discharged from the front rotary shaft flow path 152b formed inside the front end of the rotary shaft 142 of the transfer screw 140, Flows into the third flow path 153 together with the heating medium and flows into the circulation pump 180 again.

As the heating medium passes through the first flow path 151 and the second flow path 152, the jacket 160 and the blades 141 of the feed screw 140 rise to a high temperature.

The worker operates the drive motor M when the jacket 160 and the blades 141 of the feed screw 140 are lifted to a predetermined high temperature or higher and feeds the inside of the horizontal chamber 110 through the hopper 120 Sludge is injected.

When the level of the sludge becomes higher than the upper end of the jacket 160, the upper part of the upper part of the jacket 160 is lowered to the upper part of the lower part of the horizontal chamber 110, The sludge located in the jacket 160 receives less influence from the heating medium passing through the first flow path 151 inside the jacket 160 and is not smoothly dried. Therefore, the sludge is prevented from becoming higher than the upper end of the jacket 160, It is preferable to control the amount of the charge.

The sludge introduced into the horizontal chamber 110 is conveyed backward while being stirred and crushed by the conveyance screw 140 rotating in the horizontal chamber 110. In this process, the sludge is transferred to the bottom and both sides of the horizontal chamber 110 The sludge is heated to a high temperature by the jacket 160 raised to a high temperature and dried. The sludges transferred to the inside of the transfer screw 140 are transferred to the wing 141 of the transfer screw 140 raised to a high temperature So that drying is performed while rising to a high temperature.

Accordingly, the sludge introduced into the horizontal chamber 110 is uniformly dried on the outer side and the inner side in the process of moving along the feed screw 140, thereby speeding up the drying.

On the other hand, all the water vapor, gas and dust generated from the sludge in the process of drying are discharged to the outside along the exhaust duct 170. When the exhaust fan 180 is further installed in the exhaust duct 170, the exhaust fan 180 operates to cause the inside of the horizontal chamber 110 to be in a low pressure state as compared with the outside, so that the exhaust of steam, gas, And the drying speed of the sludge becomes faster.

The sludge having undergone the above-described process is discharged to the outside through the sludge discharge port 130 installed at the rear end of the horizontal chamber 110 in a state in which drying is completed.

Although not shown, the sludge drying apparatus of the present invention may be installed in a stacked state in which a hopper 120 of another sludge drying apparatus is connected to the sludge discharge port 130. In this case, if the rotation speed of the feed screw 140 is increased to increase the sludge feeding speed, the sludge throughput can be greatly improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be takeners of ordinary skill in the art, And such variations are within the scope of the present invention.

110 ... horizontal chamber 120 ... hopper
130 ... Sludge outlet 140 ... Feed screw
141 ... wing 142 ... rotational shaft
151 ... first flow path 152 ... second flow path
153 ... 3rd Euro 160 ... jacket
170 ... heater 180 ... circulating pump
152a ... wing flow passage 152b ... front rotary shaft flow passage
152c ... rear-

Claims (3)

A horizontal chamber;
A hopper for introducing the sludge to the front of the horizontal chamber;
A sludge outlet provided at a rear end of the horizontal chamber;
A transfer screw installed inside the horizontal chamber and rotating in one direction to transfer the sludge introduced into the hopper to a sludge discharge port;
A circulation flow path having a first flow path provided in the horizontal chamber, a second flow path formed along the wing of the feed screw, and a third flow path having both ends connected to the front end and the rear end of the first flow path and the second flow path, respectively;
A heating medium charged in the circulating flow path;
A heater installed on the third flow path to heat the heating medium filled in the circulation flow path; And
And a circulation pump installed on the third flow path to supply a circulation force to the heating medium. The method according to claim 1,
The second flow path
A blade flow path formed in the blade of the feed screw; And
And a front and a rear rotary shaft flow path formed in both ends of a rotary shaft of the conveying screw to connect the blade flow path and the third flow path. The method according to claim 1,
A jacket surrounding the lower portion and both side portions of the horizontal chamber is installed outside the horizontal chamber,
Wherein the first flow path is an inner space of the jacket.

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