KR101989506B1 - Rotary type dust collectiong apparatus and waste drying system using thereof - Google Patents

Abstract

According to the present invention, a rotary dust collecting apparatus is provided, which comprises: a dust collecting chamber providing a space for removing moisture and dust while hot air is introduced and exhausted; a dust collecting means configured to be rotatable inside the dust collecting chamber and to adsorb and collect moisture and dust included in the hot air; a removing means for injecting high pressure air into the dust collecting chamber in a state of being located in the inner space of the dust collecting means to remove the moisture and dust adsorbed and collected by the dust collecting means; and a dust discharge means formed at a lower side of the dust collecting chamber corresponding to a spraying direction of the removing means and discharging the moisture and dust removed. According to the present invention, the adsorption function of the filter is enhanced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary type dust collecting apparatus and a waste drying system using the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary type dust collecting apparatus and a waste drying system using the same. More particularly, the present invention relates to a system for drying waste sludge using high heat, And then circulated to the drying apparatus to reduce the production of hot air for drying the waste, thereby saving energy, and a waste drying system using the same.

Generally, sludge of wastes such as tires, vinyl and plastic used in daily life, food wastes, sewage sludge, and livestock manure are mostly recycled and mostly buried or incinerated. Among them, the method of filling the sludge causes a problem that the landfill is secured and the ground water and the ground are contaminated by the buried sludge, and therefore, a method of disposing the sludge by incineration is intensively disclosed.

On the other hand, before the sludge is incinerated, the moisture contained in the sludge must be dried. A system for drying waste by using hot air at a high temperature is disclosed in Japanese Patent No. 10-1097899.

The conventional waste drying system includes a drying device for drying the waste sludge using hot air as described above and a hot air blown from the drying device through a bag filter and a cleaning means to remove moisture And a dust collecting device for removing fine dust and the like and discharging it to the atmosphere.

However, in the conventional waste drying system, since the moisture and fine dust of the hot air discharged from the drying device through the dust collecting device are simply removed and discharged into the air, There is a problem that the energy consumed for generating hot air can not be saved.

Further, in the conventional waste drying system, in the case of the dust collecting apparatus, since moisture and dust are adsorbed to the bag filter while hot air passes through only a plurality of bag filters, moisture and dust are no longer adsorbed to the bag filter So that the adsorption function is remarkably deteriorated, and there is a problem that a large cost is required for maintenance.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a rotary type dust collecting apparatus capable of reducing energy consumed in generating hot air for drying waste by removing moisture and dust of hot air discharged from a drying apparatus, Drying system.

Another object of the present invention is to provide a rotary dust collecting apparatus and a waste drying system using the same, which can remove dust adsorbed by a rotary dust collector from a filter to improve a suction function and reduce maintenance cost.

Meanwhile, the object of the present invention is not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a dust collecting apparatus comprising: a dust collecting chamber for providing a space for removing moisture and dust as hot air flows in and out; A dust collecting means configured to be rotatable inside the dust collecting chamber and adapted to adsorb and collect moisture and dust contained in hot air; A detaching means for detaching moisture and dust adsorbed and collected by the dust collecting means by injecting high-pressure air into the dust collecting means while being positioned in the inner space of the dust collecting means; And dust discharging means for discharging water and dust which are formed on the lower side of the dust collecting chamber corresponding to the jetting direction of the removing means.

According to the present invention, there is also provided a drying apparatus for drying waste air and heated air by hot air while supplying and discharging waste and hot air; A rotary dust collecting device for removing moisture and dust contained in the hot air discharged from the drying device and then supplying the drying device; A circulation heat exchanger arranged between the drying device and the rotary dust collector to exchange heat with the external heat source so that the hot air for circulation discharged and circulated from the rotary dust collector maintains a predetermined temperature; And a supply heat exchanger for heat-exchanging the outside air with an external heat source so that the outside air supplied to the drying apparatus has a predetermined temperature to generate hot air for supply.

Therefore, according to the present invention, it is possible to reduce the energy consumed in generating the hot air for drying the waste by removing the moisture and dust of the hot air discharged from the drying device and then introducing the moisture into the drying device.

In addition, the filter adsorbed dust can be removed from the filter, thereby improving the adsorption function of the filter and reducing the maintenance cost.

On the other hand, the effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a side view of a rotary dust collector according to a preferred embodiment of the present invention;
FIG. 2 is a plan view of the rotary type dust collecting apparatus of FIG. 1;
FIG. 3 is a view showing an overall structure of a waste drying system using a rotary dust collector according to a preferred embodiment of the present invention; FIG. And
4 and 5 are views showing the construction of a heat exchanger in the waste drying system of FIG.

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

1 to 5, a rotary dust collecting apparatus 100 according to a preferred embodiment of the present invention includes a dust collecting chamber 110 for providing a space for removing moisture and dust while hot air is introduced and exhausted, A dust collecting means 120 configured to be rotatable in the dust collecting chamber 110 with a cylindrical structure and capable of adsorbing and collecting moisture and dust contained in the hot air, (130) for removing moisture and dust adsorbed and collected by the dust collecting means (120) by spraying high pressure air to the dust collecting means (120) rotated in a state where the dust collecting means And dust discharging means 140 formed at the lower side of the dust chamber 110 for discharging water and dust to be removed.

The dust collecting chamber 110 is a means for providing a space for the inflow of hot air and the exhaust and the removal of moisture and dust. The dust collecting chamber 110 includes a cylindrical housing 111, a housing 111, A hot air outlet 113 formed at an upper portion of the housing 111 and adapted to exhaust hot air from which moisture and dust are removed from the housing 111, a housing 111, A dust collecting hole 114 formed in the lower side of the housing 111 and allowing the moisture and dust removed from the hot air to be discharged to the dust discharging means 140; And a thermostat 116 which surrounds the outer circumferential surface of the housing 111 and prevents the temperature of the hot wind from being lowered.

The hot air inlet 112 preferably has a structure in which hot air discharged from the drying apparatus 200 flows into the hot air outlet 113 and hot air from which moisture and dust are removed from the hot air outlet 113 is supplied to the drying apparatus 200 .

The hot air inlet 112 may include a damper 112a for preventing the hot air flowing into the housing 111 from flowing backward.

The hot air vent 113 is detachably mounted on the upper surface of the housing 111 through a communication duct 117 which is guided by a guide frame separately protruding from the opening of the housing 111, A space for maintenance can be ensured. At this time, the outer surface of the communication duct 117 is further provided with a thermostat 117a, so that the temperature of hot air can be suppressed from being lowered.

Therefore, according to the dust collecting chamber 110, it is possible to suppress the temperature of the hot air to a minimum during the operation of removing the moisture and dust of the hot air by the heat insulating wall 115 and the thermostat 116, It is possible to save the energy consumed in generating hot air for waste drying in recycling.

The dust collecting means 120 has a cylindrical structure and is configured to be rotatable in the dust collecting chamber 110. The dust collecting means 120 is a means for attracting and collecting moisture and dust contained in the hot air, A rotating body 121 mounted on the outer circumferential surface of the rotating body 121 so that the rotating body 121 has a cylindrical structure, And a filter 123 for allowing hot air and dust to be adsorbed when the hot air flows from the outside of the rotating body 121 to the inside thereof.

Here, the dust collecting means 120 may be configured such that the inlet of the hot air outlet 113 of the housing 111 is located at the upper side of the rotating body 121 of the cylindrical structure and inside the filter 123, 112 are positioned outside the rotating body 121 of the cylindrical body and the filter 123.

Therefore, according to the dust collecting means 120, the hot air introduced into the dust collecting chamber 110 passes through the filter 123 corresponding to the wall surface of the cylindrical body and moves to the inside of the rotating body 121, At this time, even when the flow path of the hot air is fixed as the rotating body 121 is rotated, moisture and dust can be adsorbed by using the entire part of the filter 123.

The removing unit 130 injects high-pressure air into the dust collecting unit 120, which is rotated in a state where the dust removing unit 130 is located in the inner space of the dust collecting unit 120, and removes the moisture and dust that have been adsorbed and collected by the dust collecting unit 120 The filter 123 is positioned inside the rotating body 121 in a state of passing through the center of the bottom portion of the housing 111 and is extended to the filter 123 in a length corresponding to the height of the filter 123 The high pressure air is injected into the plurality of injection holes 133 and the injection pipe 131 which are formed toward the filter 123 in the injection pipe 131 and the injection pipe 131, And a high-pressure air supply tank (not shown) for allowing high-pressure air to be injected through the holes 133 to remove moisture and dust adsorbed by the filter 123 in a direction opposite to the adsorption direction.

Therefore, by removing air and dust adhering to the filter 123 by injecting high-pressure air into the filter 123 of the dust collecting means 120, the efficiency of the filter 123 is improved Maintenance costs can also be reduced.

Even if high temperature air is injected into only one part of the filter 123 as the filter 123 is rotated by the rotating body 121, moisture and dust adsorbed on the entire part of the filter 123 can be removed .

The dust discharging means 140 is a means for discharging moisture and dust which are formed on the lower side of the dust collecting chamber 110 corresponding to the jetting direction of the removing means 130, A gate 143 configured to allow the dust to be discharged to the outside by allowing the dust receptacle 141 to be opened and closed and the end of the gate 143 to open the gate 143, And a rotary valve 145 for discharging the dust to the discharge conveyor while adjusting the amount of dust to be dropped.

Therefore, according to the dust discharging means 140, water and dust removed at the lower portion of the housing 111 can be collected by the removing means 130 and discharged to the outside.

Hereinafter, the operation of the rotary type dust collector 100 according to the preferred embodiment of the present invention will be described.

First, the hot air discharged from the drying apparatus 200 flows into the hot air inlet 112 of the dust collecting chamber 110. At this time, the filter 123 of the dust collecting unit 120 installed in the dust collecting chamber 110 receives the hot air 121).

After the hot air passes through the filter 123 and is moved to the inner space of the rotating body 121, the hot air is exhausted through the hot air outlet 113 of the dust collecting chamber 110 and re-introduced into the drying apparatus 200. At this time, The filter 123 absorbs moisture and dust contained in the hot air.

High pressure air is injected from the inside to the outside of the filter 123 by the detaching means 130 located inside the rotating body 121 of the dust collecting means 120, Moisture and dust are removed in the opposite direction.

Thereafter, dust collected in the dust collection port 114 of the dust collecting chamber 110 is discharged to the outside by the dust discharging means 140.

Therefore, according to the rotary dust collecting apparatus 100 of the present invention, moisture and dust of the hot air discharged from the drying apparatus 200 are removed by the filter 123 and then introduced into the drying apparatus 200, It is possible to reduce the production of hot air generated at a high temperature for the purpose of reducing energy consumption.

In addition, since the dust adsorbed to the filter 123 is removed from the filter 123, the adsorption function of the filter 123 can be improved and the maintenance cost can be reduced.

1 to 5, a waste drying system using a rotary dust collecting apparatus according to a preferred embodiment of the present invention includes a drying apparatus for drying waste by hot air while supplying and discharging waste and hot air, A rotary type dust collecting apparatus 100 for removing moisture and dust contained in the hot air discharged from the drying apparatus 200 and then supplying the dried powder to the drying apparatus 200 and a rotary type dust collecting apparatus 100 between the drying apparatus 200 and the rotary type dust collecting apparatus 100 A heat exchanging device 300 for circulating heat exchanged with an external heat source so that hot air circulated and exhausted from the rotary type dust collecting device 100 maintains a predetermined temperature and an outside air supplied to the drying device 200 is heated to a predetermined temperature And a heat exchanger (400) for supplying heat to generate heat by exchanging heat with an external heat source.

The drying apparatus 200 is a device for drying waste or waste sludge through hot air. The drying apparatus 200 includes a drying chamber 210 having a tubular structure and having a structure in which waste is supplied and discharged and hot air is supplied and discharged, And a conveyor means 230 configured to dry the waste by zigzag while being heated by hot air.

The drying chamber 210 is a means for providing a space for drying the waste while supplying and discharging the waste and the hot air. The drying chamber 211 is formed in the upper part of the drying housing 211, A hot air supply port 212 for supplying hot air heat-exchanged by the heat exchanging device 300 for circulation and the heat exchanging device 400 for supply to the inside of the drying housing 211, A hot air discharge port 213 for discharging the hot air supplied to the inside of the drying housing 211 to the rotary type dust collecting apparatus 100, a hot air outlet 213 for discharging hot air from the waste supply device (not shown) A waste outlet 215 formed at a lower portion of the drying housing 211 for discharging waste that has been dried outside the drying housing 211, And the air layer A heat insulating wall body 216 for preventing the temperature of the hot air from being lowered and a drying heat insulating body 217 for covering the outer circumferential surface of the drying housing 211 and suppressing the temperature of hot air from being lowered, .

Here, the waste supply port 214 receives waste from the hopper to the waste supply device, and the waste discharge port 215 supplies the dried waste to a known discharge conveyor device so that the corresponding process is performed.

Therefore, according to the drying chamber 210, the temperature of the hot air can be suppressed to a minimum during the drying operation of the waste by the heat insulating wall 216 for drying and the warming body 217 for drying, So that the energy consumed in generating the hot air for drying the municipal waste can be saved.

The conveyor means 230 is constructed by a plurality of zigzags arranged inside the drying housing 211 so that the waste is moved in a staggered manner and dried by hot air. The conveyor means 230 has a known structure, and thus a detailed description thereof will be omitted.

Therefore, according to the drying apparatus 200, the waste can be dried by the hot air and discharged. At this time, as the waste moves in a zigzag manner, the drying time due to the hot air is increased to improve the drying efficiency.

The rotary type dust collecting apparatus 100 is a device for removing moisture and dust contained in the hot air discharged from the drying apparatus 200 and then supplying the drying apparatus 200 to the drying apparatus 200 so that moisture and dust are removed A dust collecting means 120 configured to be rotatable in the dust collecting chamber 110 while having a cylindrical structure and capable of adsorbing and collecting moisture and dust contained in the hot air, A detaching means 130 for detaching moisture and dust adsorbed and collected by the dust collecting means 120 by spraying high pressure air to the dust collecting means 120 rotated in a state where the dust collecting means 120 is located in the inner space of the dust collecting means 120, And dust discharging means 140 formed at a lower portion of the dust collecting chamber 110 corresponding to the spraying direction of the means 130 and discharging moisture and dust to be removed.

Here, since the rotary type dust collector 100 has the above-described structure, a detailed description thereof will be omitted.

The circulating heat exchanger 300 is provided between the drying apparatus 200 and the rotary type dust collector 100 and performs heat exchange with the external heat source so that hot air circulated and exhausted from the rotary type dust collector 100 maintains a predetermined temperature The apparatus includes a heat exchange tube 310 in which hot air for circulation is supplied and discharged from a circulation blower F1 connected to a rotary type dust collector 100, A heat exchanging means 320 installed in the space in a zigzag or spiral shape to heat exchange the hot air for circulation to a predetermined temperature by the exothermic fluid filled in the inner space of the heat exchange tube 310, A heat insulating wall for heat exchange which suppresses the temperature of the hot air from being lowered, and a heat exchanger for cooling the heat exchanger, It includes a body or the like.

On the other hand, the amount of hot air supplied to the circulation heat exchanger 300 by the circulating blower F1 has a ratio of 70% to the total hot air exhausted from the rotary type dust collector 100, The remaining 30% of the total hot air exhausted from the exhaust pipe is supplied to the exhaust air deodorization furnace (not shown) and treated by a known method.

Here, the reason why the amount of hot air supplied to the circulating heat exchanger 300 has a ratio of 70% to the total hot air exhausted from the rotary type dust collector 100 is that the amount of hot air that is much more or less than 70% The heat exchange rate of the heat exchanging means 320 is significantly lowered and the energy consumption is increased.

Therefore, it is preferable that the amount of the hot air supplied to the circulation heat exchanger 300 by the circulating blower F1 has a critical significance as described above.

The heat exchanging means 320 is welded to the outer circumferential surfaces of the heat exchanging tubes 321 and the heat exchanging tubes 321 in a zigzag manner at constant intervals in the heat exchanging tube 310 to improve the strength of the heat exchanging tubes 321, Shaped heat transfer plate 322 and a heat transfer plate 322 which are formed in the shape of an letter "L" so as to generate a resistance against the moving direction of circulating hot air, And a heat transfer fin 323 that enables high heat exchange of hot air for circulation through turbulent flow formed inside the heat exchanger 310.

At this time, the heat transfer plate 322 is joined to the outer circumferential surface of the heat exchange tube 321 at an oblique angle so as to have a spiral structure. Through this, turbulence such as eddy current is formed when hot air for circulation passes through the heat exchange tube 321, It is preferable to increase the contact time with the contact portion 321.

A plurality of heat transfer plates 322 are joined to the outer peripheral surface of the zigzag heat exchange tube 321 and the heat transfer fins 323 are further formed at the edges of the heat transfer plates 322, It is preferable that the hot air for circulation supplied to the heat exchanger 310 maintains a temperature of 150 ° C to 170 ° C, preferably 160 ° C.

The heat exchange unit 320 has a structure in which a large number of protrusions are simply joined to improve the heat transfer area of the heat exchange tube 321 as the heat transfer plate 322 is joined to the outer peripheral surface of the heat exchange tube 321, It is possible to provide a heat transfer area which is higher than or equal to the heat transfer area, and the bonding operation can be relatively easily performed. Thus, the workability can be improved by improving the bonding structure.

Thus, according to the circulating heat exchanger 300, 70% of the circulating hot air discharged from the rotary type dust collector 100 is circulated to the drying apparatus 200 in a state of being heat-exchanged at a temperature of about 150 ° C to 170 ° C, The waste drying efficiency can be improved as compared with the case where the waste heat is circulated in a state where heat exchange is not performed.

The supply heat exchanger 400 is a device for generating hot air by exchanging heat with an external heat source so that the outside air supplied to the drying device 200 has a predetermined temperature and the outside air is supplied and discharged from the blower F2 for supply The heat exchange tubes 410 are installed in a zigzag or spiral shape in the internal space of the heat exchange tube 410 in a state of being extended from combustion, heating and other heat sources, and the outside air is heat-exchanged at a predetermined temperature by the heat- A heat insulating wall for heat exchange which is formed on the wall surface of the inner circumferential surface of the heat exchanging cylinder 410 so as to form an air layer so as to prevent the temperature of the hot air from being lowered and an outer circumferential surface of the heat exchanging cylinder 410 And a heat-insulating thermostat for suppressing the temperature of the hot air from being lowered.

Here, the configuration of the heat exchanging means 420 of the heat exchanging device 400 for supplying is the same as that of the heat exchanging device 400 except that the outside air supplied to the heat exchanging device 410 is maintained at a temperature of 170 占 폚 to 190 占 폚, preferably 180 占 폚 And the heat exchanging means 320 of the circulating heat exchanging apparatus 300, detailed description thereof will be omitted.

Therefore, according to the heat exchanger for supplying 400, hot air having a temperature of about 170 ° C to 190 ° C is supplied to the drying apparatus 200, so that the waste drying efficiency can be improved as compared with the case where only outside air is supplied.

According to the present invention, hot air for circulation supplied from the circulation heat exchanger 300 and hot air for supply supplied from the supply heat exchanger 400 are supplied to the drying apparatus 200.

Thus, in the present invention, the amount of the hot air for circulation and the amount of hot air for supply is mixed at a ratio of 7: 3 in anticipation of a loss of a predetermined amount of heat during the movement to the drying apparatus 200, (Not shown) for allowing the hot air to be supplied to the drying apparatus 200 at a temperature of about 140 ° C. due to the loss of a certain amount of heat during the movement to the drying apparatus 200.

The reason why the hot air supplied to the drying apparatus 200 by the hot air ratio adjusting device has a temperature of about 140 ° C is that when the temperature is higher than the above temperature, the waste is burned or only the outside is instantaneously dried, If the temperature is lower than the above temperature, the glue zone in which the waste sludge collects in a predetermined size becomes long, so that the waste in the bulk state in the conveying means of the drying apparatus 200 is adsorbed So that there is a problem that the efficiency of drying the waste is greatly reduced.

Therefore, it is preferable that the temperature of the hot air supplied to the drying apparatus 200 by the hot air ratio adjusting device has a critical significance as described above.

When the temperature of the hot air supplied to the drying apparatus 200 is about 140 ° C, the temperature of the hot air discharged from the drying apparatus 200 generally has a temperature of 100 ° C or less, The energy consumed by the heat exchange for the supply hot air is larger than the energy consumed by the heat source.

Therefore, when the amount of hot air for circulation and the amount of hot air to be supplied to the drying apparatus 200 are controlled at a ratio of 7: 3, the heat exchange efficiency is improved during heat exchange with hot air of 170 DEG C, Can be saved.

That is, when the amount of circulating hot air and the amount of hot air to be supplied to the drying apparatus 200 have a ratio of 6: 4, for example, energy consumption for heat exchange of the outside air with the hot air for supply becomes large, It takes a long time to heat the hot air for circulation by the hot air of 170 DEG C, thereby lowering the heat exchange efficiency.

Therefore, it is preferable that the ratio of the amount of circulating hot air to the amount of hot air to be supplied to the drying apparatus 200 by the hot air ratio adjusting device has a critical significance as described above.

Hereinafter, a method of drying a waste in a waste drying system using a rotary dust collector according to a preferred embodiment of the present invention will be described.

First, waste and hot air are introduced into the drying apparatus 200, and the waste is dried by hot air.

The hot air discharged from the drying apparatus 200 flows into and out of the rotary type dust collecting apparatus 100. At this time, the moisture and dust contained in the hot air flowing into the rotary type dust collecting apparatus 100 are collected by the dust collecting means 120 Removed.

Thereafter, the hot air for circulation which is exhausted from the rotary type dust collector 100 is heat-exchanged at a predetermined temperature by the circulating heat exchanger 300.

Thereafter, the hot air for circulation is mixed with hot air for supply generated by the heat exchanger 400 for supply, heat-exchanged at a predetermined temperature, and then, the hot air is introduced into the drying apparatus 200.

Therefore, according to the waste drying system of the present invention, the moisture and dust of the hot air discharged from the drying apparatus 200 are removed by the filter 123 and then introduced into the drying apparatus 200, It is possible to reduce the production of generated hot air, thereby saving energy use.

Although the present invention has been described with reference to the specific embodiments, various modifications may be made without departing from the scope of the present invention. Accordingly, the scope of the invention is not to be determined by the embodiments described, but should be determined by equivalents of the claims and the claims.

Claims (8)

A dust collecting chamber 110 for providing a space for allowing moisture and dust to be removed as hot air is introduced and exhausted; A dust collecting means 120 configured to be rotatable in the dust collecting chamber 110 and adapted to adsorb and collect moisture and dust contained in hot air; A detaching means (130) for spraying high pressure air to the dust collecting means (120) rotated in a state of being located in the internal space of the dust collecting means (120) to remove moisture and dust collected by the dust collecting means (120); And dust discharging means 140 formed at a lower portion of the dust collecting chamber 110 corresponding to the spraying direction of the removing means 130 and discharging moisture and dust to be removed,
The house truth room (110)
A tubular housing 111;
A hot air inlet 112 formed at one side of the housing 111 and allowing hot air to flow into the housing 111;
A hot air vent 113 formed at an upper portion of the housing 111 to exhaust hot air from which moisture and dust are removed to the outside of the housing 111;
A dust collecting hole 114 formed in the lower portion of the housing 111 and allowing moisture and dust removed from the hot air to be discharged to the dust discharging means 140;
A heat insulating wall 115 formed on the wall surface of the inner circumferential surface of the housing 111 to prevent the temperature of hot air from being lowered by forming an air layer; And
And a thermostat (116) configured to surround the outer circumferential surface of the housing (111) and to prevent the temperature of the hot wind from being lowered,
The dust collecting means (120)
A rotating body 121 installed inside the housing 111 and rotated by the driving means;
The rotating body 121 is provided on the outer circumferential surface of the rotating body 121 so that the rotating body 121 has a cylindrical structure and the hot air introduced into the housing 111 moves in the direction from the outside to the inside of the rotating body 121, And a filter (123)
The detaching means (130)
A spray pipe 131 located inside the rotating body 121 in a state of passing through the housing 111 and extending to the filter 123 in a length corresponding to the height of the filter 123;
A plurality of injection holes 133 formed in the injection pipe 131 toward the filter 123 to inject high-pressure air; And
Pressure air supply tank for introducing high-pressure air into the injection pipe 131 and injecting high-pressure air through the injection hole 133 to remove water and dust adsorbed by the filter 123 in a direction opposite to the adsorption direction, (Not shown)
The dust discharging means (140)
A dust receptacle 141 formed in the dust collection port 114 of the housing 111;
A gate 143 for allowing dust to be discharged to the outside by opening and closing the dust receptacle 141; And
And a rotary valve (145) formed at an end of the gate (143) for discharging the dust while regulating the amount of dust falling upon opening of the gate (143). delete delete delete delete A drying device (200) for drying the waste and hot air by hot air while being supplied and discharged;
A rotary type dust collecting apparatus 100 for removing moisture and dust contained in hot air discharged from the drying apparatus 200 and supplying the dried dust collecting apparatus 200 to the drying apparatus 200;
A circulation heat exchanger 300 configured to be installed between the drying apparatus 200 and the rotary type dust collector 100 to exchange heat with the external heat source so that the hot air for circulation to be exhausted and circulated from the rotary type dust collector 100 is maintained at a predetermined temperature, ; And
And a supply heat exchanger (400) for generating hot air for supply by exchanging heat with an external heat source so that the outside air supplied to the drying apparatus (200) has a predetermined temperature,
The rotary type dust collector (100)
A waste drying system having the configuration according to claim 1. The drying apparatus (200) according to claim 6,
A drying chamber 210 having a structure in which waste is supplied and discharged with a tubular structure and hot air is supplied and discharged;
And a conveyor means (230) arranged inside the drying chamber (210) for drying the waste by zigzag and drying by hot air,
The drying chamber (210)
A drying housing 211;
A hot air supply port 212 formed at an upper portion of the drying housing 211 and adapted to supply hot air heat-exchanged by the circulating heat exchanger 300 and the feed heat exchanger 400 into the drying housing 211;
A hot air outlet 213 formed at a lower side of the drying housing 211 and allowing the hot air supplied into the drying housing 211 to be discharged to the rotary type dust collector 100;
A waste supply port 214 formed at the upper side of the drying housing 211 and allowing waste to be supplied from the waste supply device (not shown) into the drying housing 211;
A waste outlet 215 formed at a lower portion of the drying housing 211 and allowing waste to be dried outside the drying housing 211 to be discharged;
A drying insulating wall body 216 formed on the inner circumferential wall surface of the drying housing 211 so as to form an air layer so as to prevent the temperature of hot air from being lowered; And
And a drying thermosensitive body (217) configured to surround the outer circumferential surface of the drying housing (211) and to prevent the temperature of the hot air from being lowered. delete

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