KR970002632B1 - Sludge drying apparatus and method - Google Patents

Abstract

The present invention related to a method of drying sludge to improve dry efficiency by heating from inside of solidified sludge and remove moisture contained in sludge by using radiation, convection current, transmission due to infrared rays complexly.The present invention comprise a process of forming designated form by giving press sludge; a process of drying formed sludge by heating and transferring in closed space; a process of circulation air in said closed space through passage connected and passed with said closed space with both ends side; a process of removing moisture from air circulated through passage of said closed space.

Description

Sludge drying method and apparatus

1 and 2 are cross-sectional views showing an example of a conventional sludge drying apparatus.

3 is a perspective view of a sludge drying apparatus according to the present invention.

4 is a cross-sectional view of the sludge drying apparatus shown in FIG.

5 is a partially cutaway perspective view of the sludge shaping means.

6 is a perspective view showing another embodiment of the sludge shaping means.

7 is a cross-sectional view showing a duct provided with a blowing means and a dehumidifying means.

8 is a view showing a refrigeration cycle of the dehumidification means.

9 is a view showing a state in which the evaporator of the dehumidification means is installed.

* Explanation of symbols for main parts of the drawings

51: main body 60: transfer means

70: sludge shaping means 80 heating means

90: blowing means 110: dehumidifying means

The present invention relates to a sludge drying method and apparatus, and more particularly, to a method and apparatus for drying sludge which is industrial waste generated in the dyeing and paper manufacturing process.

In general, industrial waste, sludge, etc. generated by treating wastewater discharged from dyeing and paper manufacturing processes are dehydrated to 80% to 90% by mechanical or physical methods, and landfilling or ocean dumping is performed. .

Many apparatuses for dehydrating and drying such sludges have been developed. Conventional sludge drying apparatuses of the related art use waste heat generated in a factory or heat sludge by heating using a separate boiler.

Figure 1 shows an example of such a conventional sludge drying apparatus.

This is provided in a main body 11 having a predetermined cavity 1la formed therein, a rotating shaft 12 provided to be rotatable vertically in the interior of the main body 1l, and at a predetermined interval from each other on the outer circumferential surface of the rotating shaft 12. And a disc 13 formed alternately with an opening 13a at a side adjacent to the rotation shaft 12 and a lower portion of the main body 11 to drive the rotation shaft 12 at a predetermined rotation speed. Geared motor 14 which is a means is provided. And a feed feeder 15 which is installed at the upper portion of the main body and is a sludge supply means for supplying sludge to the disc, and a discharge feeder 16 disposed at the lower portion of the main body 11 to discharge dried sludge; The main body 11 is provided with the burner 17 for heating the cavity 11a, and the blower 18 for discharging the high temperature and humid gas inside the said cavity to the outside.

The conventional sludge drying apparatus 10 configured as described above supplies the sludge from the feed feeder 15 to the disc 13 installed on the rotary shaft 12, and drives the motor 14 to drive the disc 13. Rotate The burner 17 is operated to heat the inside of the cavity. In this way, the sludge supplied to the disc 13 is moved to the bottom as the disc 13 is rotated, dried, and then discharged to the outside through the discharge feeder 16 installed at the bottom of the main body 11.

In another embodiment of the conventional sludge drying apparatus, as shown in FIG. 2, the rotating drum 23 is supported by a plurality of guide rollers 22 installed on the frame 21, and both ends thereof cover the cover member 24 and the outlet. Hopper 25 provided with (25a) is provided so as not to be affected by the rotation of the rotary drum (23). In addition, a duct 26 having a plurality of through holes 26a and a braid 26b is provided at a central portion of the rotary drum 23, and a blower 27 is installed at one end of the duct 26. The cover member 24 is provided with a hopper 28 for supplying sludge to the rotary drum 23 and a burner 29 for supplying hot air. The rotating drum 23 is rotated by a motor 33 connected to the rotating shaft by a spriget 31 and a chain 32 in which a drum is installed along a main surface thereof.

In the conventional sludge drying apparatus configured as described above, when the rotary drum 23 is rotated by the motor 33 and hot air is supplied to the inside of the rotary drum 23 by the burner 29, sludge is supplied from the hopper 28. After drying, the gas in the rotating drum, which is hot and humid, is discharged through the through hole 26a of the duct 26 and the blower.

The conventional sludge apparatus as described above has the following problems.

First: Sludge adheres to the disk or rotating drum, which is the transfer device, and the transfer efficiency is reduced.

Second: The sludge is excessively bumped into each other, which generates a lot of dust.

Third, production costs increase due to the addition of equipment to purify dust and hot and humid gases.

Fourth: The fuel cost of heating the sludge to a high temperature is increased.

Fifth: Condensation phenomenon due to temperature difference when discharging hot and humid gas causes excessive drying rate when supplying drying air.

Sixth; When the sludge is dried by hot air, the sludge is dried from the outer surface, thereby reducing the sludge drying efficiency.

Seventh: burning fuel such as a burner is getting heat, so there is a possibility of causing air pollution.

The present invention was created to solve the above problems, by using a combination of radiant convection conduction by infrared radiation to remove the water contained in the sludge and heated from the inside of the solidified sludge to improve the drying efficiency The object is to provide a drying method and an apparatus thereof.

Another object of the present invention is to provide a sludge drying apparatus that can reduce the loss of heat due to the sludge heating to reduce the maintenance cost according to the operation.

In order to achieve the above object, the present invention, in the sludge drying method for drying the sludge, pressurizing the sludge to form a predetermined shape, and drying step of heating and drying while transporting the shaped sludge in a closed space And a passage through which the enclosed space and both ends thereof communicate with each other to circulate the air in the enclosed space through the passage, and a dehumidification step of removing water from the air circulated through the passage of the enclosed space. Its features, including that.

And the sludge drying apparatus of the present invention, the main body is provided with a predetermined cavity therein, the conveying means for transferring the sludge step by step at predetermined intervals in the cavity, and the sludge installed in the upper portion of the main body to solidify the sludge A blowing means provided with a solidifying means, heating means for heating the sludge installed inside the main body, and a duct for sucking air in the main body from one side of the main body and supplying it to the other side of the main body; It is characterized in that it is provided with a dehumidifying means for removing moisture from the gas transported in the duct.

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

Sludge drying method for drying the industrial waste discharged from the dyeing, paper manufacturing process, etc., pressurizing the sludge to form a predetermined shape, drying step of heating and drying while transporting the shaped sludge in a closed space, A passage through which the enclosed space and both ends thereof communicate is formed to circulate the air in the enclosed space through the passage, and a dehumidification step of removing water and foreign matter from the air circulated through the passage of the enclosed space. It was to include.

Here, when the sludge is generated by the microorganisms in the molding step of forming the sludge into a predetermined shape, it is preferable to apply a predetermined potential to the sludge so that the destruction of the microorganisms and the discharge of the internal water from the location can be performed smoothly. In addition, it is preferable to store heat released during dehumidification by applying heat circulating the passage. In addition, it is preferable to heat the sludge in the drying step and irradiate infrared rays and maintain the heating temperature between 160 degrees and 180 degrees.

An apparatus according to the present invention suitable for carrying out the method has a main body 51 having a predetermined cavity 51a provided therein as shown in FIGS. 3 and 4, and mutually predetermined in the cavity 51a. Transfer means 60 for transferring the interval sludge 200 in a step-down, sludge shaping means 70 is formed on the upper portion of the main body 51 to shape the sludge 200, and the main body 51 Heating means 80 for heating the sludge 200, which is installed inside and transported by the conveying means 60, and sucks the air inside the main body 51 from one side of the main body 51 of the main body 51 It is roughly divided into a blowing means 90 provided with a duct 91 for supplying the inside to the other side, and a dehumidifying means 110 for removing moisture from the gas that is installed and transported in the duct 91.

The conveying means 60 is installed in the main body 51 to transfer the sludge in stages, and is provided with a plurality of belt conveyors installed in parallel with each other in the horizontal direction and spaced apart from each other by a predetermined interval in the vertical direction. . Here, the plurality of conveyors installed in the vertical direction are alternately installed in the longitudinal direction of each other and the sludge supplied to the upper conveyor so that the rotation is rotated in the opposite direction to the adjacent conveyor is preferably continuously supplied to the lower conveyor. Do.

The belt conveyor has a pair of rollers (61, 61 ') rotatably mounted at both sides of the main body (51) and supported on both sides of the main body (51), and these rollers (61) (61). It is configured to include a belt (62) to be caught, it is preferable that the belt 62 is used that is formed with a plurality of through holes (62a). In addition, although not shown in the drawing, a driving means such as a geared motor is installed on at least one side of the rotation shaft 61a of the rollers 61 and 61 '. This driving means is preferably provided for each of the plurality of conveyors or to be able to drive each conveyor at the same time. And the lower part of each conveyor is provided with the scraper 65 which removes the foreign material adhering to the belt 62 of the conveyor.

The sludge shaping means 70 presses the sludge to shape the sludge into a predetermined shape, and two kinds of roller type and screw type are applied according to the state of the sludge. As shown in FIG. 4, the roller-type sludge shaping means has a forming roller 73 which is in close contact with and rotatably installed in the body 72 in which the hopper 71 is installed, and which drives the forming roller 73. It is provided with a drive means. Herein, the driving means preferably uses a geared motor, and a groove 73a is formed in the circumferential direction along the outer circumferential surface of the molding roller 73 so that sludge is formed by the groove 73a. This is preferable, it is preferable to apply different potentials to the forming roller (73).

The screw-type sludge shaping device has a cylindrical body 72 'provided with a hopper 71' on one side of the cylindrical body 72 ', as shown in FIG. 5, and rotatable to the body 72. And a nozzle 74 'installed at the end of the cylindrical body 72' to discharge the sludge, and a driving means for rotating the screw 73 '. The upper and lower portions of the inner circumferential surface of the cylindrical body 72 'is preferably made of a conductor so that different potentials can be applied, and the upper and lower portions are separated and pickled.

The heating means 80 is installed on the inner circumferential surface of the main body 51 to dry the sludge moved by the transfer means 60, it is configured with an infrared heater 81 provided on the inner circumferential surface of the main body.

The blowing means 90 circulates the air in the cavity 51a of the main body 51, and as shown in FIG. 6, the cavity 51a and the upper surface of the main body 51 and the lower side of the main body 51 are lowered. A duct 91 is provided so as to communicate with it, and the duct 9l is provided with the normal blowing unit 92 provided with the fan which can circulate the air in the cavity 51a. In addition, a residual gas exhaust pipe 94 having a damper 94a is provided at an upper portion of the duct 91. Here, at least one side of the inlet side or the outlet side of the Soongpung unit 93 is preferably provided with a filter 94 for filtering to remove dust from the gas to be sucked, the lower end of the duct 91 and the main body 51 The lower side of the side is preferably provided with a plurality of branch pipes (95).

The dehumidifying means 110 removes moisture by cooling the gas blown from the air blowing unit 93 to the duct 91 below the dew point temperature, as shown in FIGS. 6, 7 and 8. Refrigeration systems are used. This includes an evaporator 111 having a plurality of grooved heat pipes 111a, a compressor 112 for sucking heat exchange medium through the evaporator 111, a condenser 113 connected to the discharge port of the compressor 112, and a condenser. An expansion valve 114 installed between the 113 and the evaporator 112, that is, the inlet side of the evaporator, forms a closing flow of the heat exchange medium, and the evaporator 111 is located inside the duct 91. And the outlet side passing through the evaporator 111 is further provided with a heat transfer heater 120 for heating the cooled air. Reference numeral 200 is sludge.

The operation of the sludge drying apparatus according to the present invention configured as described above and the sludge drying method through this operation will be described in detail as follows.

In order to dry the sludge using the sludge drying apparatus according to the present invention, first, the conveyor, which is the conveying means 60 installed in the cavity 5la, is operated, and the infrared heater 81 which is the heating means is operated.

In this state, the sludge 200 subjected to the primary dewatering treatment by the mechanical and physical method is supplied to the hopper 71 of the sludge shaping means 70. The sludge supplied to the hopper 71 is molded into a predetermined shape by the groove 73a formed on the main surface of the roller 73 while the pair of rollers 73 are rotated. In this process, since the pair of rollers 73 are applied with different potentials, electrical shock is applied to the sludge to be press-molded to destroy microorganisms. Therefore, the water present between the cells or particles of the microorganism is ionized in a state that is easy to remove.

The sludge 200 shaped by the sludge shaping means 70 is moved away from the belt 62 of the moving conveyor, and when the temperature inside the cavity 51a reaches a predetermined temperature, the duct ( The blowing unit 92 installed in the 91 is operated to circulate the air supplied to the cavity 51a of the main body 51, and the compressor 112 of the dehumidifying means 110 is operated. The heating heater 95 provided on the outlet side is operated.

As described above, the sludge 200 continuously moved by the conveyor in a state where each part is operated is dried and sterilized from the inside by infrared rays and heat emitted from the infrared heater 81, and the inside of the cavity 51a. Since the gas is continuously circulated through the duct 91 by the blowing unit 92, the drying effect can be improved.

In more detail, the movement of the sludge by the plurality of conveyors spaced apart by a predetermined interval in the horizontal direction, which is the transfer means 60, is moved to the lower conveyor when the movement by the upper conveyor is completed. Since the scraper 65 is provided at the lower portion of each conveyor, the sludge 200 is left to move attached to the belt 62 in which the plurality of through holes 62a are formed. The sludge 200 moved in this way can improve the evaporation effect due to the airflow induced in the cavity 51a in the air blowing unit 92, thereby improving the drying efficiency of the sludge 200.

In the process of drying the sludge 200 as described above, the moisture is removed from the gas flowing through the inside of the duct 91 by the dehumidifying means 110 described above, which will be described in detail.

Since the evaporator 111 connected to the inlet of the compressor 112 and the inlet of the compressor 112 are installed in the duct 91, the moisture contained in the gas is condensed by falling below the dew point temperature. Will be able to remove. That is, the heat exchange medium passing through the evaporator 111 from the condenser 113 through the expansion valve 114 is evaporated after the evaporator 111 maintained at a low pressure by the compressor 112 evaporates from the inside, and then evaporates the latent heat of vaporization. The compressed gas is compressed through the compressor 112 and is condensed to the condenser 113 to release and liquefy the latent heat of evaporation and heat according to the amount of compression. Since a plurality of heat dissipation tubes are installed on the surface of the evaporator 111 cooled by the above operation, the gas passing through the inside of the duct 91, that is, the saturated gas including the water evaporated from the sludge 200 is cooled to provide moisture. This condensation removes moisture from the gas.

The gas from which water is removed as described above is heated while passing through the heating heater 120 installed at the outlet side of the duct 91, and then the cavity of the main body 51 through the branch pipe 95 installed at the lower portion of the duct 91. To be supplied.

As described above, the gas supplied to the cavity removes water evaporated from the sludge while the gas discharged from the sludge 200 is circulated as described above.

As described above, the sludge drying method and the apparatus of the present invention can reduce the loss of calories because the sludge is dried at a low temperature using an infrared heater and water is removed while circulating the air in the cavity. In addition, the present invention can be sanitary treatment can be obtained by heating the sludge with an infrared heater, there is an advantage that can reduce the air pollution because it does not use heat by the combustion of fuel.

Claims (10)

In the sludge drying method for drying the sludge, pressurizing the sludge into a predetermined shape, drying step of heating and drying the shaped sludge while transporting it in a closed space, and the sealed space and both ends thereof are passed through. And a dehumidifying step of circulating air in the sealed space through the passage and removing moisture from the air circulated through the passage of the closed space. The sludge drying apparatus according to claim 1, wherein the water contained in the sludge is ionized by applying an electric shock when the sludge is shaped. A sludge drying apparatus comprising: a main body provided with a predetermined cavity therein; a conveying means for transferring the sludge stepwise to the cavity at a predetermined interval; and a sludge shaping means provided on the upper part of the main body to shape the sludge; And, the heating means is provided inside the main body for heating the sludge conveyed by the conveying means, the blowing means provided with a duct for sucking the air inside the main body from one side of the main body to supply the other side of the main body, and the duct Sludge drying apparatus, characterized in that provided with a dehumidifying means for removing moisture from the gas to be transported. 4. The sludge drying apparatus according to claim 3, wherein the sludge shaping means is rotatably provided with a pair of rollers having grooves formed on an outer circumferential surface of the sludge shaping means. The sludge drying apparatus according to claim 4, wherein a predetermined electric potential is applied to each of the rollers so that an electric shock can be applied to the sludge passing therebetween. The sludge drying apparatus according to claim 3, wherein the heating means is an infrared heater. The sludge drying apparatus according to claim 3, wherein a filter is installed inside the duct. The sludge drying apparatus according to claim 3, wherein the conveying means comprises a plurality of belt conveyors spaced apart from each other by a predetermined interval in a horizontal direction. The sludge drying apparatus according to claim 8, further comprising a scraper in close contact with a belt at the bottom of the conveyor. The sludge drying apparatus according to claim 3, wherein the dehumidifying means is a refrigerating means having an evaporator installed in a duct.