KR20090052261A - Apparatus for drying sludge and, methods for sludge processing - Google Patents

Abstract

The present invention relates to a sludge drying apparatus and a sludge treatment method, and more particularly, to reduce the time and cost required for sludge drying, to increase energy efficiency, and to prevent marine environmental pollution and odors. It relates to a drying apparatus and a sludge treatment method. The sludge drying apparatus of the present invention for this purpose, the upper plate; Bottom plate; An elevating unit for elevating at least one of the upper plate and the lower plate to be in close contact with the other one; And a heating unit for heating at least one of the upper plate and the lower plate. After the sludge is applied to the lower plate, the sludge is heated by the heating unit in a state where the upper plate and the lower plate are in close contact with each other.

Sludge, Drying, Adherence, Flat Plate, Static Drying, Renewable Energy

Description

Apparatus for drying sludge and, methods for sludge processing}

The present invention relates to a sludge drying apparatus and a sludge treatment method, and more particularly, after applying a sludge thinly to the lower plate or placing the sludge in the form of a string having a predetermined thickness, the upper plate is in close contact with the sludge and the upper plate The present invention relates to a sludge drying apparatus and a sludge treatment method for overcoming various drying resistances of sludge by heating the bottom plate and rapidly transferring thermal energy to the sludge to dry the sludge.

In general, the sewage treatment process consists of a water purification process that removes contaminants from the sewage and discharges them into clear water, and a sludge treatment process that concentrates the removed contaminants into sludge, dehydrates them, and discharges them.

In the sludge treatment process, as shown in FIG. 1, in order to reduce the amount of sludge generated, an expensive large digester is installed and the sludge is kept in the digester for about 20 days, and about 30% is decomposed into methane gas and carbon dioxide. (Digestion step), the hydrogen sulfide generated together with the gases are incinerated (desulfurization, incineration step), and the digested sludge is concentrated and dehydrated (concentration and dehydration step) and then taken out as waste (waste removal step) It is currently dumping in the ocean.

Various organic sludges generated in such sewage treatment or livestock farms are treated by ocean dumping due to the domestic waste management law, because the waste management law prohibits the landfilling of sludge having a water content of 75% or more. The amount of ocean dumping is increasing rapidly from 107 million tonnes in 1990 to 7.1 million tonnes in 2000 and 9.993 million tonnes in 2005.

This ocean dumping causes marine environmental pollution. As the new regulation of the London Convention on the Prevention of Marine Pollution enters into force on March 24, 2006, it is necessary to reduce the amount of dumping of marine sludge. Various technologies and devices have been developed. However, the technology and the device is still insufficient performance to replace the ocean dumping.

On the other hand, organic sludge, such as sewage sludge, livestock wastewater and food waste, has a high calorific value of dry matter (dried sludge has more than 3500 Kcal per kilogram), which makes it highly valuable as a renewable energy resource, while its water content is 80%. Since there are so many that the amount of heat retained cannot be used as energy, the development of the sludge drying apparatus which heats sludge and evaporates the water in sludge was tried.

The sludge drying apparatus developed so far is classified into a direct drying method in which the heated air is directly contacted with the sludge to supply thermal energy, and the steam or oil is first heated by the combustion heat to remove the heat medium (steam or oil). It is divided into indirect drying method which heats sludge secondarily using heat energy.

In the direct drying method, the sludge drying apparatus using this method has been developed because the thermal efficiency is higher than the indirect drying method and the equipment is simple because the high temperature combustion gas and sludge are in direct contact. However, in the direct drying method, the dried water vapor is discharged together with the combustion gas, and some organic matter is burned in the drying process, causing severe odors due to environmental problems, causing enormous civil complaints around the environment, and thermal efficiency is low to about 30%, which leads to high fuel costs. Therefore, there is a problem that the economy is less than ocean dumping.

Indirect drying method uses a burner to heat steam or oil first, and this steam or oil heats a drying container or disc to form a hot plate, which comes in contact with the sludge to supply heat energy to the sludge and remove moisture. This is the method of drying the sludge, and the exhaust passage of the combustion gas and water vapor can be separated from each other to prevent odor and reduce civil complaints.However, the indirect drying method has lower thermal efficiency than the direct drying method, and the sludge is attached to the device during drying. Many problems occur.

As such, the conventional sludge drying apparatus by the direct drying method and the indirect drying method is generally economical because the drying efficiency is very low and thus requires more drying energy than drying the sludge and recovering it as renewable energy. Therefore, at present, most organic sludge is dumped at sea, and the low efficiency of drying of the conventional sludge drying apparatus is because it does not properly overcome various drying resistances of the sludge as a drying target.

Looking at the drying resistance of the sludge, one-step drying resistance and two-step drying resistance are shown. Among them, the one-step drying resistance is as follows.

First, a large amount of drying energy is required for sludge drying. Since water, which takes up more than 80% of the weight of sludge, requires 540 Kcal / kg of evaporation energy, it delivers enormous drying energy of more than 500,000 Kcal per ton of sludge into the sludge. What should be done is the biggest drying resistance. In order to transfer such enormous drying energy quickly, a heat transfer medium with high heat transfer efficiency is required. The air used in the conventional sludge drying apparatus has not only an extremely low thermal conductivity but also a very low specific heat of 0.309 Kcal / ℃, which is required for sludge drying. It is not suitable as a heat medium to transfer large-scale heat energy.

Second, the cell fluid inside the cell membrane of the microorganism constituting the sewage sludge is not removed by general evaporation drying. Cell solution inside the cell membrane can be removed only by heat drying.

Third, no matter how much the temperature of the drying device increases in order to speed up the heat transfer in the heat drying of the sludge, since the outer sludge absorbs all the heat energy first and vaporizes water with water vapor to maintain 100 ° C, vaporization of water vapor inside the sludge The heat transfer blocking phenomenon occurs, in which the heat energy supply necessary for the heat is cut off. Since the sludge is sequentially dried from the surface of the heat transfer blocking phenomenon, the heat energy required for drying is blocked.

Fourth, when the sludge is dried, an empty space is generated by evaporation of water, which occupies 80% of the initial volume, and the empty space becomes a strong insulating layer filled with water vapor or air with extremely low thermal conductivity. Such a heat insulating layer is formed on the outside where sequential drying is performed, and as the drying proceeds, the heat insulating layer becomes thick, thereby rapidly reducing heat energy transfer into the sludge which needs to be dried.

Due to the third and fourth causes, the sludge in contact with the hot plate overheats and burns, resulting in an extreme drying imbalance in which the sludge inside is kept wet, delaying drying and maintaining the drying apparatus at a high temperature for a long time. In order to consume a lot of fuel.

In order to solve the one-stage drying resistance of the sludge, a method of stirring the sludge so that the undried wet sludge is in contact with the hot plate and promotes drying is used. appear. Two-stage drying resistance, combined with one-stage drying resistance, causes complex and various problems.

First, when the sludge is agitated to improve the dry imbalance of the sludge, the dried sludge and the undried sludge are mixed with each other, and the adhesive components of the sludge stick together to form a sludge mass. In this case, the heat insulation layer is formed on the outside again to block the transfer of heat energy to the inside of the lump, and the inside of the lump is kept in an undried state, and the sludge drying time is 20 minutes even when the sludge is stirred in the drying step by the adhesion resistance. It takes longer than that.

Second, due to the change in the physical properties of the sludge, the very soft sludge before drying, the properties change and become very hard when dried. Therefore, the agglomeration is not broken well even when stirred, and the adhesive component is coated on the hardened surface to decrease the drying speed. The sludge adhering to the stirring device hardens in a hard state to block the internal passage of the drying device, thereby stopping the operation of the elaborately designed drying device and lowering the operating efficiency of the facility.

As mentioned above, the conventional drying technology does not solve the one-stage drying resistance, so it stirs up to the two-stage drying resistance. As a result, the sludge drying efficiency is significantly low, which consumes a lot of fuel, and in order to compensate for the low efficiency. Due to the large size of the equipment, which requires a lot of facility investment costs, the economy is low, and the sludge can not be dried and internationally criticized, except in some special cases where the state supports the cost of sludge drying or freely uses the dry energy. Disposal by sea dumping.

In addition, as described above, in the sewage treatment plant, sludge is stored in a large digester for about 20 days in order to reduce sludge generated in large quantities, and about 30% of the sludge is decomposed into methane gas and carbon dioxide (digestion step). The digester is not only expensive, but also cannot disassemble the entire sludge, so a separate facility for storing and transporting the sludge to treat the remaining 70% of the sludge as waste is needed. Therefore, not only the construction cost of the sewage treatment plant is expensive, but also many environmental problems are caused by bad smell and methane gas in the sludge treatment process.

The present invention solves the heat transfer blocking, heat insulation layer formation and the drying resistance of the sludge, such as adhesion resistance and physical property changes occurring in the existing drying method, and a new drying device that can quickly transfer a large amount of heat energy required for sludge drying and sludge treatment using the same The purpose is to provide a method.

Another object of the present invention is to reduce the drying time of the sludge to about 5 minutes and to increase the drying thermal efficiency of the sludge to 80% or more to provide a sludge drying apparatus and method that is economically competitive compared to ocean dumping.

Still another object of the present invention is to provide a sludge drying apparatus and method which can be easily and securely treated with sludge treatment automatically and continuously, and minimizes the scale of the equipment on the basis of high efficiency, thereby lowering facility investment cost and maintenance cost. There is.

Another object of the present invention is to condense and recover all the water vapor generated in the drying process of the sludge so that the odor is not leaked to the outside so that the odor problem caused by the sludge treatment does not occur, and the thermal energy required for drying incinerated the dried sludge It is possible to reduce the energy cost, which accounts for most of the sludge drying costs, thereby providing an economical sludge drying apparatus and method.

Another object of the present invention is to immediately treat the sludge generated in the sewage treatment plant, eliminating the need for expensive sludge reducing facilities, and to prevent the occurrence of methane gas or odor generated during the transport and storage of sludge. Therefore, to provide an economical and environmentally friendly sludge drying apparatus and method.

In order to achieve the above object, the sludge drying apparatus according to the present invention has the following configuration.

In order to dry the sludge effectively, the air with very poor heat transfer characteristics is eliminated as much as possible. The upper and lower plates with high thermal conductivity are brought into direct contact with the sludge to supply heat energy quickly, and the upper and lower plates per unit volume of the sludge are contacted. Maximize the area so that a large amount of heat energy is supplied.

In addition, the adhesion resistance among the drying resistance of the sludge is generated when the sludge is moved, the adhesive resistance is an important cause to hinder the drying of the sludge, in the present invention supplies heat energy into the sludge in the state in which the sludge does not move.

Another drying resistance heat transfer blocking phenomenon is a phenomenon that occurs when the sludge is 'sequentially dried', in the present invention, to minimize the heat transfer blocking phenomenon, the sludge is applied thinly and uniformly in a plane to be dried at a time.

As an alternative to applying the sludge thinly and evenly in a plane, the present invention places the sludge in the form of a string having a predetermined thickness, with the sludge in the form of a string being placed on the lower plate so as to have a predetermined interval. Since the sludge in a row form is pressurized by the upper flat plate and gradually heated, the steam can be effectively discharged, and the sludge is prevented from being splashed between the lower flat plate and the upper flat plate by the steam while the sludge is heated.

The insulation layer, which is the biggest difficulty in overcoming the sludge drying resistance, is a problem caused by the evaporation of 80% of the water contained in the sludge to create an empty space.The thickness of the sludge in contact with the upper and lower plates is as thin as possible, By supplying heat energy to the bottom plate, the heat transfer distance is reduced by half to minimize the occurrence of heat insulation layer. In addition, in the drying process in which 80% of the initial volume is reduced, the upper plate is brought into close contact with the lower plate by its own weight to minimize the heat insulation layer.

In addition, when the sludge and the upper and lower plates are in direct contact with each other, it is very good and efficient in terms of transferring thermal energy, but it is difficult to discharge water vapor generated by evaporation of moisture to the outside. If the water vapor cannot be discharged, the water cannot vaporize with water vapor, the vapor pressure of the water increases, the internal temperature of the sludge rises to the same temperature as the upper and lower flat plates, and the heat energy supply is stopped and the drying is stopped. In order to solve this problem, the upper and lower flat plates are adhered to the sludge thinly coated on both sides to supply thermal energy to the sludge, and the upper and lower flat plates are periodically spaced to discharge steam. As an alternative, the upper and lower flat plates are in close contact with the sludge formed in the form of a string so that the sludge unfolds to supply thermal energy, and the upper and lower flat plates are periodically spaced to discharge water vapor.

In this way, the sludge is made thin (for example, about 2 mm thick) or in the form of a string, and the upper and lower plates are moved between the upper and lower plates while the upper and lower plates are adhered and heated on both sides of the sludge. As the sludge does not move in the sludge drying process and the sludge drying resistance does not occur, the sludge dries quickly. When heated by the lower plate, the heat transfer distance is short and no heat transfer is blocked.If the upper and lower plates are in close contact with each other, there is no empty space between the upper and lower plates and the sludge, so no insulation layer is generated, and the sludge is between the upper and lower plates. Sticking resistance occurs because only the internal moisture is evaporated with water vapor while being supplied with heat energy without moving at all. Not only does not, is pressed, an empty space of the drying sludge by evaporation is too great the adhesive effect of the hot plate.

When heat energy is supplied to the upper and lower flat plates of about 160 ° C from both sides from 2mm thin sludge, the energy supply per unit volume of sludge is greatly increased, and the sludge drying time can be shortened to about 5 minutes, thereby improving the thermal efficiency of the drying apparatus. .

The higher the temperature of the upper and lower flat plates and the thinner the sludge, the shorter the drying time, but the higher the cost of fuel and equipment, etc., so the temperature of the hot plate and the thickness of the sludge are determined and used accordingly. At atmospheric pressure, water begins to vaporize at 100 ° C, and pyrolysis of sludge begins at 250 ° C. Therefore, the temperature of the upper and lower flat plates is preferably about 100 ° C to 200 ° C.

When the upper and lower flat plates are coated using Teflon, which is resistant to high temperatures of 250 ° C. and does not adhere, the adhesive effect of the sludge does not stick to the hot plate during the drying process, thereby improving the adhesion between the upper and lower flat plates.

The upper and lower plates are moved in a circular motion and are repeated close to each other. The upper and lower flat plates are spaced apart from each other in the section in which the coating member and the removing member are installed. Therefore, the sludge may be applied by the coating member and the sludge may be removed by the removing member. When passing through the section, the upper plate is lowered to be in close contact with the lower plate and the heat energy of the heated plate is supplied to the sludge.

On the other hand, the odorous water vapor of 100 ℃ discharged from the sludge is moved to the condensing unit because it is lighter than the air. The condensation unit cools the water vapor to condensate.

Another condensation unit cools and condenses the steam moved up with the cooling water contained in the upper cover, and the condensate formed by cooling and condensing the water vapor falls down. The condensate that falls down is led to the wall by the condensate guide roof.

The dried sludge has more than 3500Kcal of heat per kg and can be burned easily, so it is incinerated in the heating furnace and used as dry energy of the sludge.

In particular, the dried sludge according to the present invention is easily burned because the coating layer of the adhesive component is not formed on the surface without undergoing the stirring process. In addition, the space from which water (water vapor) is discharged becomes voids, and combustion is facilitated because these voids are evenly distributed in the sludge.

If the sludge treatment process is configured to immediately dry the sludge discharged from the sewage treatment plant by connecting the sludge drying device to the sludge dehydrator of the sewage treatment plant, an expensive digester installed and operated for the purpose of reducing 30% of the sludge is not needed. The sludge storage facility installed and operated for the discharge of sludge is not needed, and the odor generated from the storage and transportation of sludge can be prevented and the new sewage treatment plant is treated more environmentally and economically by discharging it without discharging sludge. I can make it.

The present invention has the following effects.

First, it is possible to quickly transfer a large amount of thermal energy required for sludge drying while solving the sludge drying resistance such as heat transfer blocking, heat insulation layer formation, adhesion resistance and physical property change occurring in the conventional sludge drying method.

Second, the drying time of the sludge is reduced to about 5 minutes and the drying thermal efficiency of the sludge is higher than 80%, which is economically competitive compared to ocean dumping.

Third, the sludge treatment can be done easily and securely because it is automatically and continuously operated, and the facility investment cost and maintenance cost can be reduced by minimizing the device size based on high efficiency.

Fourth, to prevent condensation problems caused by sludge treatment by condensing and recovering all the water vapor generated during the drying process of sludge, and drying the sludge because the heat energy required for drying is obtained by incineration of the dried sludge. It is economical because it can reduce the energy cost which accounts for most of the cost.

Fifth, the sludge generated in the sewage treatment plant can be treated immediately, and the digester, an expensive sludge reduction facility, is not needed, and it is economical and environmentally friendly by preventing the generation of methane gas or odor generated during the transportation and storage of sludge. to be.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only embodiments of the present invention and do not represent all of the technical idea of the present invention, various equivalents that may be substituted for them at the time of the present application It should be understood that there may be variations and variations.

On the other hand, the sludge drying apparatus of the present invention can be used to treat not only sewage sludge generated in the sewage treatment process, but also organic sludge generated during the treatment of livestock wastewater, food waste, and the like. Therefore, in the present invention, the sludge is used to include all of these organic sludges.

2 is a plan view showing a sludge drying apparatus according to a first embodiment of the present invention, Figures 3a to 3e is a schematic diagram showing a process of removing the sludge after the sludge is applied and heated in the sludge drying apparatus.

Referring to the drawings, the sludge drying apparatus 100 is a lower plate 10, the upper plate 20 installed on the upper portion of the lower plate 10, and the upper plate 20 is raised so as to be in close contact with the lower plate 10. It includes a lifting unit for lowering, a heating unit 50 for heating the upper plate 20 and the lower plate 10, and a transfer unit for transferring the upper plate 20 and the lower plate 10.

The lower plate 10 and the upper plate 20 are heated by a heating unit 50, and the heated upper plate 20 and the lower plate 10 are heated and dried while pressing the sludge 1 from both sides.

Preferably, the upper and lower flat plate 20, 10 is provided with a plurality. When the upper and lower flat plates 20 and 10 are transferred by the transfer unit, the sludge 1 is applied, the sludge 1 is heated, and the sludge 1 is sequentially removed. The sludge treatment operation can be performed efficiently, such that the amount of sludge 1 present increases.

The lower plate 10, as shown in Figures 4a to 4c, is preferably mounted on the upper surface of the connecting portion 72 and the connecting portion 72 is preferably connected to the chain member (74). Therefore, when the chain member 74 is moved, the lower flat plate 10 and the upper flat plate 20 mounted on the connecting portion 72 are moved. The connection portion 72 is described below.

The lower plate 10 and the upper plate 20 are heated by the heat medium oil supplied from the heating unit 50. The heat medium oil is respectively supplied to the upper and lower flat plates 20 and 10 through the supply pipe 52 and discharged from the upper and lower flat plates 20 and 10 through the recovery pipe 53, respectively. Inside the lower plate 10 and the upper plate 20, a hollow path in which a moving path or a heating medium in which the heat medium oil is moved may stay for a predetermined time. Since the thermal oil is commonly used for heating, description thereof will be omitted.

Preferably, the lower flat plate 10 is provided with a guide rod 12 and the upper flat plate 20 is formed with a guide hole into which the guide rod 12 can be inserted, and the upper flat plate 20 is connected to the guide rod 12. Ascend and descend as guided by.

At least a portion of the upper plate 20 and the lower plate 10 in contact with the sludge 1 is preferably coated with Teflon that is resistant to high temperatures (eg, 250 ° C.) and does not stick. If the part of the upper plate 20 and the lower plate 10 contacting the sludge 1 is coated with Teflon, the adhesive component of the sludge 1 does not stick to the upper plate 20 and the lower plate 10 during the drying process. It is not effective.

As described above, the upper and lower flat plates 20 and 10 exclude the air having very poor heat transfer characteristics, and allow the upper and lower flat plates 20 and 10 and the sludge 1 to be in direct contact with each other so that thermal energy is quickly contacted. To supply. In addition, the contact area with the upper and lower flat plates 20 and 10 per unit volume of the sludge 1 is maximized so that a large amount of thermal energy is rapidly supplied.

In addition, since the upper and lower flat plates 20 and 10 supply thermal energy into the sludge 1 in a state in which the sludge 1 is fixed, adhesion resistance does not occur.

In addition, the upper and lower flat plates 20 and 10 allow thin and uniformly applied sludge 1 to be temporarily dried to overcome the heat transfer blocking phenomenon.

On the other hand, as described above, when the water contained in the sludge 1 evaporates, an empty space (that is, a heat insulating layer) is generated inside the sludge 1 to block heat transfer into the sludge 1, While making the thickness of the sludge 1 as thin as possible (the sludge 1 is applied to the lower plate 10 in a thin thickness, or placed in the lower plate 10 in the form of a predetermined thickness of the upper plate 20) When pressurized, the thickness becomes thin.) By supplying heat energy from both sides of the sludge (1), the heat transfer distance is reduced by half to minimize the occurrence of the insulation layer and at the same time, the upper plate (20) in the drying process reduces 80% of the initial volume. By allowing the sludge 1 to be pressed under a load of), the dried sludge 1 may be adhered to a thin plate and the heat insulation layer may be smoothly transferred to the inside of the sludge 1 because the heat insulating layer is minimized.

Lifting roller 22 is provided on the upper surface of the upper flat plate 20, the lifting roller 22 will be described below.

Preferably, the sludge 1 is applied to the lower plate 10 by the supply unit 40. As shown in FIGS. 5 and 6, the supply unit 40 has a predetermined thickness of the sludge 1 on the lower plate 10 while the upper plate 20 and the lower plate 10 are moved apart from each other. It includes a coating member 42 provided between the lower flat plate 10 and the upper flat plate 20 so as to be thinly coated, and a conveying unit for transferring the sludge 1 to the coating member 42.

The coating member 42 discharges the sludge 1 to a uniform thickness of a predetermined thickness, for example, about 2 mm through an applicator. The applicator has a width corresponding to the width of the lower plate 10. In the present specification, the applicator has a 'corresponding width', which means that the applicator has a width capable of uniformly applying the sludge 1 at a time to the moving lower plate 10. For example, the applicator has a width 20 mm smaller than the width of the lower plate 10.

The coating member 42 is installed at a position corresponding to the guide part 30 because the sludge 1 is applied to the lower flat plate 10 while the upper flat plate 20 and the lower flat plate 10 are moved apart from each other. It is preferable to be. The guide portion 30 will be described below.

The conveying part conveys the sludge 1 to the application member 42. The transfer part includes a cylinder member 44, a propeller member 44a provided inside the cylinder member 44, a pump 43 communicating with a lower end of the cylinder member 44 and the application member 42.

The cylinder member 44 is a hollow inside, and a hollow propeller member 44a is provided so that rotation is possible. The propeller member 44a moves the injected sludge 1 downward.

The propeller member 44a has a plurality of pairs of wings provided at predetermined intervals along the axis. The wing pair is a plurality of wings arranged at a predetermined angle around the axis. The dewatered sludge 1 has a high lubricity (that is, slipperyness) and a high adhesiveness, and is difficult to transport using a screw. That is, when the screw is installed inside the cylinder member 44, since the sludge 1 is attached to the screw, it is difficult to inject the sludge 1 into the inlet 43a while applying pressure to the sludge 1. In contrast, the propeller member 44a is suitable for conveying the sludge 1 because a plurality of vanes are arranged around the axis at a predetermined angle, and the pair of vanes is arranged along the axis at predetermined intervals. The propeller member 44a injects the sludge 1 into the inlet 43a while applying a predetermined pressure to the sludge 1.

The inlet 43a of the pump 43 communicates with the lower end of the cylinder member 44, and the discharge port 43b of the pump 43 communicates with the application member 42. The pump 43 moves the sludge 1 to the application member 42 while applying pressure to the sludge 1 introduced by the propeller member 44a.

As the pump 43, a monopump was generally used. A monopump has a problem in application to a sludge having high wear because the rubber stator of the rotor and the stator, which generate injection pressure, are weak to abrasion. This lowers and is not suitable. Therefore, in the present invention, it is preferable to use the rotary gear pump 43 to replace the mono pump.

The rotary gear pump 43 transfers fluid by a combination of male and female gears made of stainless steel resistant to abrasion and corrosion, thus exhibiting a very strong discharge pressure against wear and maintaining pressure and quantity even in a small amount of transfer.

The rotary gear pump 43 is provided with an inlet 43a at right angles to the axial direction thereof, so that it is difficult to suck a material having low flowability, such as sludge 1, in the present invention, the inlet 43a of the rotary gear pump 43 By connecting the cylinder member 44 to solve the suction problem and connecting the discharge port 43b with the coating member 42, the sludge 1 can be extruded to a desired thin thickness by the strong discharge pressure of the rotary gear pump 43. . In addition, if the drive speed of the rotary gear pump 43 is controlled by an inverter, the extrusion speed can be adjusted as desired, so that the sludge 1 is suitably applied.

On the other hand, the dried sludge 1 is preferably removed from the lower plate 10 by the removal member 47. The removal member 47 is installed on the lower plate 10 to separate the sludge 1 loaded on the lower plate 10 being moved from the lower plate 10. That is, the upper plate 20 is in close contact with or spaced apart from the lower plate 10 by the elevating unit (ie, the guide part 30) while being transported by the transfer unit, and the removal member 47 is disposed on the upper plate 20. ) And the dried sludge 1 is separated from the lower plate 10 while the lower plate 10 moves in the spaced apart state. Removal member 47 is installed at a height lower than the thickness of the dried sludge (1).

As the removal member 47, a screw or a wiper (not shown) may be used. The screw is rotated by the motor to separate the sludge 1 loaded on the lower plate 10 from the lower plate 10. The removed sludge 1 is discharged to the outside along the blade of the screw, and then loaded into the sludge cylinder 49 provided separately.

The elevating unit raises and lowers the upper plate 20 so that the upper plate 20 is in close contact with or spaced apart from the lower plate 10. The sludge 1 is applied and the sludge 1 is removed while the upper flat plate 20 is raised by the elevating unit.

As shown in FIG. 6, the elevating unit includes a guide portion 30 for guiding the elevating roller 22, and the guide portion 30 is the upper flat plate when the elevating roller 22 is moved while being guided. An upward inclined portion 31 to raise the 20, a downward inclined portion 32 to lower the upper plate 20, and a horizontal portion connecting the upward inclined portion 31 and the downward inclined portion 32 ( 33). Preferably, a guide groove (35 in FIG. 10) is formed in the guide portion 30 along its length direction, and the lifting roller 22 for moving along the guide groove 35 is moved.

When the lowering roller 22 enters the upward inclined portion 31 while the upper flat plate 20 and the lower flat plate 10 are moved by the transfer unit, the upper flat plate 20 moves while being moved up and down. When the roller 22 enters the horizontal portion 33, the upper flat plate 20 moves while maintaining the horizontal, and when the lifting roller 22 enters the downward inclined portion 32, the upper flat plate 20 This will move while descending.

On the other hand, Figure 7 is a perspective view showing a modification of the supply unit provided in the sludge drying apparatus, Figures 8a to 8e is removed after the sludge is applied and heated when the sludge is supplied by the supply unit of FIG. It is a schematic diagram showing the process. 7 to 8E, the same reference numerals as the reference numerals of FIGS. 3A to 3E and 5 denote the same components having the same functions.

The supply unit 41 has a lower plate 10 and an upper plate 20 so that the sludge 1 can be applied to the lower plate 10 while the upper plate 20 and the lower plate 10 are moved apart from each other. ) And a conveying part for transferring the sludge 1 to the coating member 42. Since the transfer unit is the same as the transfer unit of the supply unit 40 described above, description thereof will be omitted.

The applicator 45 includes an applicator of a predetermined size. The applicator is formed at predetermined intervals.

As shown in FIG. 8B, the applicator 45 discharges the sludge 1 having a predetermined thickness through the applicator to the lower flat plate 10 at predetermined intervals. 8C and 8D show that the sludge 1 is pressed by the upper plate 20, where water vapor generated while the sludge 1 is being slowly pressed and heated through the space 1a between the sludge 1 is shown. Since the upper and lower flat plates 20 and 10 are in close contact with each other, it is possible to prevent the phenomenon that the sludge 1 protrudes to the side while steam is discharged. Preferably, when the sludge 1 is pressed at a constant speed so that the sludge 1 is gradually pressed for a time of about 5-20 seconds, the sludge 1 is effectively adhered between the upper flat plate 20 and the lower flat plate 10.

The heating unit 50 is provided with a heating furnace 51 for heating the heat medium oil and a heating medium oil installed inside the chain member 74 and rotated and heated at the same speed as the moving speed of the chain member 74. The rotating member supplied from 51 and the upper plate 20 and the connecting pipe 56 is installed to connect the rotating member and the lower plate 10 and the rotating member. The heat medium oil heated in the heating furnace 51 is supplied to the upper flat plate 20 and the lower flat plate 10 through the rotating member and the connecting pipe 56.

The heating furnace 51 burns fuel to heat the heat medium oil. Preferably, the already-dried sludge 1 is burned to heat the heat medium oil. The dried sludge 1 is effective in heating the heat medium oil because of high calorie content. In addition, the use of the dried sludge 1 as fuel is very advantageous in terms of environmental and cost savings.

The heat medium oil heated in the heating furnace 51 is supplied to the upper rotating member 55a through the supply pipe 52, and then heats the upper and lower flat plates 20 and 10. The heating medium oil which heated the upper and lower flat plates 20 and 10 is moved to the lower rotating member 55b, and is recovered to the heating furnace 51 through the collection pipe 53. The supply pipe 52 is preferably connected at the center of the upper end of the upper rotating member 55a because the upper rotating member 55a rotates, and the recovery pipe 53 has a lower rotating member because the lower rotating member 55b rotates. 55b is preferably connected at the center of the lower end.

The rotating member is a cylindrical member, and consists of an upper rotating member 55a on the upper portion of the cylinder and a lower rotating member 55b on the lower portion of the cylinder, with a partition formed in the middle. The upper rotary member 55a and the lower rotary member 55b are rotated at the same speed because they are connected to each other.

The upper rotary member 55a rotates at the same speed as the feed rate of the chain member 74 and supplies heat medium oil to the connection pipe 56. The upper rotating member 55a is connected to the plurality of connecting pipes 56 at the side thereof. That is, the heat medium oil is supplied to the upper and lower flat plates 20 and 10 through the upper rotating member 55a and the connecting pipe 56.

The lower rotating member 55b recovers the heat medium oil from the connecting pipe 56 while rotating at the same speed as the feed speed of the chain member 74. The lower rotating member 55a is connected to the plurality of connecting pipes 56 at the side thereof. That is, the heat medium oil discharged from the upper and lower flat plates 20 and 10 is moved to the lower rotating member 55b through the connecting pipe 56.

The connecting tube 56 connects the upper rotating member 55a and the upper flat plate 20 and connects the lower rotating member 55b and the lower flat plate 10. The connection pipe 56 is preferably made of a flexible material, which is to prepare for the case where the moving speed of the upper plate 20 and the lower plate 10 and the rotational speed of the rotating member slightly differ.

The transfer unit transfers the upper plate 20 and the lower plate 10. The transfer unit includes a chain member 74 circulated in a caterpillar by a drive motor, and a connection portion 72 connecting the chain member 74 and the lower plate 10. The upper and lower flat plates 20 and 10 are loaded on the connecting portion 72, and the connecting portions 72 are connected to the chain members 74, so that the upper and lower flat plates 20 and 10 are connected by the chain members 74. ) Is moved. Preferably, the wheel 75 is installed on the lower surface of the connection portion 72.

In addition, while the sludge 1 is applied to the lower plate 10 by the coating member 42, the coating member 42 is a straight section of the chain member 74 so that the adjacent lower plate 10 is in close contact with each other. It is preferably installed in. The sludge 1 is continuously discharged from the application member 42 because some of the sludge 1 falls to the bottom when the adjacent lower plate 10 is spaced apart from each other.

Preferably, the sludge drying apparatus 100 includes a condensation unit 60 installed above the upper plate 20 to condense the water vapor generated from the heated sludge 1. The water vapor contains odors.

The condensation unit 60 includes a sealing member 62 for sealing the upper and lower flat plates 20 and 10 and the transfer unit, a condensation tube 63 communicating with an upper end of the sealing member 62, and a condensation tube 63. Cooling water pipe 64 passing through the inside of the) is provided.

Since the water vapor discharged from the sludge 1 is lighter than air, the water vapor rises upward. The sealing member 62 is installed to seal the upper and lower flat plates 20 and 10 and the transfer unit, and an upper end of the sealing member 62 is provided. When the condensation tube 63 is in communication with each other, water vapor moves to the condensation tube 63. The water vapor collected in the condensation tube 63 is condensed by the cooling water passing through the cooling water pipe 64 to be condensed water. The condensate is moved to a sewage treatment plant (not shown) via the cooler 65.

On the other hand, when the suction blower 66 is installed on the upper end of the cooling water pipe 64 and sucked at a pressure of 500 mmHg, the cooling water heated by the water vapor evaporates to generate low pressure steam of about 89 ° C. The low pressure steam is recycled as energy, and the low pressure steam is environmentally safe because no odor is included. If it is not necessary to use low pressure steam, the heated cooling water is used directly or spontaneously evaporates in the atmosphere.

9 is a plan view showing a sludge drying apparatus according to a second embodiment of the present invention, FIG. 10 is a perspective view showing a transfer unit, a lifting unit, an upper flat plate and a lower flat plate of the sludge drying device, FIG. 11A 11C is a perspective view showing that the upper plate of the sludge drying apparatus is operated.

The sludge drying apparatus 200 is a lowering unit 10 for lowering and lowering the lower plate 10, the upper plate 20 installed on the upper portion of the lower plate 10, and the upper plate 20 to be in close contact with the lower plate 10. And a heating unit 150 for heating the upper plate 20 and the lower plate 10, a transfer unit for transferring the upper plate 20 and the lower plate 10, and a sludge 1 to the lower plate 10. ), A supply unit 40 to be applied to the), a removing member 47 to remove the sludge 1 from the lower plate 10, and a condensation unit 60 to condense water vapor.

Among the components of the sludge drying apparatus 200, the lower plate 10, the upper plate 20, the elevating unit, the transfer unit, the supply unit 40, the removal member 47, the condensation unit 60 described above The lower plate 10, the upper plate 20, the lifting unit, the transfer unit, the supply unit 40, the removal member 47, the condensation unit 60 of the sludge drying apparatus 100 of the first embodiment, respectively It has a structure of principle. Therefore, the detailed description of the lower plate 10, the upper plate 20, the elevating unit, the transfer unit, the supply unit 40, the removal member 47, the condensation unit 60 will be omitted.

The sludge drying apparatus 200 has a feature of describing a method of heating the upper plate 20 and the lower plate 10 using electricity without using heating medium oil as a heating unit.

To this end, the heating unit 150 includes a carbon brush 151 installed at the connection portion 72, an electric supply rail 152 installed to contact the carbon brush 151, and a power source 155. The carbon brush 151 is electrically connected to the upper and lower flat plates 20 and 10. Therefore, electricity is supplied to the upper and lower flat plates 20 and 10 through the electric supply rail 152 and the carbon brush 151. The electricity supply rail 152 is installed along the movement path of the upper and lower flat plates 20 and 10 to supply electricity to the upper and lower flat plates 20 and 10 that are moving. This structure of the heating unit 150 has the same principle as the current collector for supplying electricity to the train.

The chain member 174 of the transfer unit is installed in an elliptical endless track orbit extending to one side. The chain member 174 is driven by the drive motor 174a.

As shown in FIG. 9, the chain member 174 may be arranged in an elliptical shape that is elongated to one side, but may be arranged in any form such as a square or a hexagon. Since the electricity is supplied to the upper and lower flat plates 20 and 10 by using the carbon brush 151 and the rail for supplying electricity 152, the electricity to the upper and lower flat plates 20 and 10 is heat transfer oil. It is advantageous when the drying apparatus 100 is small because it is easier than supply.

The same heating medium heating method as the first embodiment can be applied to the second embodiment, and the electric heating method like the second embodiment can be applied to the first embodiment, which is easily understood by those skilled in the art with reference to the present specification. Since it is understood, the description will be omitted.

On the other hand, Figure 12 is a perspective view showing a sludge drying apparatus according to a third embodiment of the present invention, Figure 13a to Figure 13f is a perspective view showing the assembled state of each part in the sludge drying apparatus.

Referring to the drawings, the sludge drying apparatus 300 includes a transfer unit, a lower plate 210 rotated by a transfer unit, an upper plate 220 installed on an upper portion of the lower plate 210, and an upper plate 220. It includes a lifting unit 230 for raising and lowering so as to be in close contact with the lower plate 210, and a heating unit 250 for heating the upper plate 220 and the lower plate 210.

The transfer unit includes a circular base frame 271 that is rotated by a drive source, a support 273 provided on the base frame 271, and a guide installed on the upper end of the support 273 and rotated together with the base frame 271. Flat plate 275.

Gears are formed on the outer circumferential surface of the base frame 271. Since the gear meshes with the gear of the drive gear 271a, the base frame 271 is rotated by the drive gear 271a. As shown in FIG. 13A, a through hole 271b is formed at the center of the base frame 271, and a rail 254 for electricity supply is installed at the through hole 271b. The electricity supply rail 254 is installed to be fixed to the lower frame 272, and the carbon brush 252 is installed to be rotatable to the electricity supply rail 254. The carbon brush 252 and the rail for supplying electricity 254 are described below.

Preferably, the base frame 271 is provided with a support member 271c at predetermined intervals, and the support member 271c supports the lower plate 210.

As shown in FIG. 13B, the support 273 is installed around the through hole 271b and rotates together with the base frame 271. A support hole 273a is formed in the support 273, and an electric wire (not shown) connecting the carbon brush 252 and the lower plate 210 through the through hole 273a and the carbon brush 252 and the upper plate are provided. An electric wire (not shown) connecting 220 passes through.

As shown in FIG. 13D, the guide plate 275 is installed at an upper end of the support 273 and rotates together with the base frame 271. A guide hole 275a is formed in the guide plate 275, and the guide holes 275a are formed at intervals at which the upper flat plate 220 is installed. The upper flat plate 220 is installed in the guide hole 275a to be able to move up and down.

The lower plate 210 is installed in the base frame 271, preferably the support member 271c. The lower plate 210 is installed to be in close contact with the neighboring lower plate 210, in order to prevent the sludge 1 from falling down. In order to install the lower plate 210 to be in close contact with each other, the lower plate 210 is connected to each other by using the connection member 211.

The lower plate 210 is heated by receiving electrical energy through the carbon brush 252 and the rail for supplying electricity 254.

The application member 45 and the removal member 47 are installed on the upper side of the lower plate 210. The sludge 1 discharged from the coating member 45 is rotated while being heated by the lower plate 210 and the upper plate 220, and then removed by the removal member 47. This is achieved by the same principle as in the above-described embodiment.

The upper plate 220 is heated by receiving electric energy through the carbon brush 252 and the rail for supplying electricity 254. The upper flat plate 220 is installed in the guide hole 275a so that the lifting and lowering is possible by the lifting unit.

The lifting roller 222 is installed on the upper surface of the upper flat plate 220. The lifting roller 222 will be described below. Preferably, the guide bar 225 is installed on the upper flat plate 220. The guide rod 225 is inserted into the guide hole of the guide flat plate 275 to guide the lifting and lowering of the upper flat plate 225.

The elevating unit raises or lowers the upper flat plate 220 so that the upper and lower flat plates 220 and 210 are spaced apart from each other or closely contact each other.

The lifting unit includes an upper frame 231 provided above the lower frame 272 and a guide part 233 formed on one side of the upper frame 231.

The upper frame 231 includes a perforation portion 235 formed at the center thereof, and the perforation portion 235 has a diameter corresponding to the diameter of the lifting roller 222.

The guide part 233 is formed around the perforation part 235. The guide part 233 may include an upward inclination part 233a for raising the elevating roller 222, a horizontal part 233b for horizontally moving the elevating roller 222 raised by the upward inclination part 233a, and It includes a downward inclined portion 233c for moving the lifting roller 222 down. The section in which the guide part 233 is installed is a section in which the upper and lower flat plates 220 and 210 are spaced apart, and the removal member 47 and the application member 45 are installed.

When the lifting roller 222 is raised along the upward slope 233a, the upper plate 220 is spaced apart from the lower plate 210, and the lifting roller 222 is removed while moving along the horizontal portion 233b. After the sludge 1 is removed by the member 47, the sludge 1 is applied by the application member 45. After the sludge 1 is removed and applied, the lowering roller 222 moves along the downward inclined portion 233c and the upper flat plate 220 is in close contact with the lower flat plate 210.

Preferably, the auxiliary guide portion 234 is installed on the rear side of the downward inclined portion 233c to protrude horizontally. The auxiliary guide portion 234 has a gentle downward slope than the downward slope portion 233c. Therefore, in the auxiliary guide part 234, the upper flat plate 220 is gently lowered, and the upper flat plate 220 is in contact with the sludge 1, but there is a slight gap in which the water vapor of the sludge 1 can be discharged. It is formed between 210 and. Therefore, since the water vapor may be discharged through the gap, it is possible to prevent the sludge 1 from protruding sideways between the upper and lower flat plates 220 and 210.

The heating unit 250 heats the upper and lower flat plates 220 and 210. As shown in FIG. 13A, the heating unit 250 rotates together with the base frame 271 in contact with the rail for supplying electricity 254 installed in the through hole 271b and the rail for supplying electricity 254. It is installed so that it includes a carbon brush 252 for supplying the electrical energy supplied through the rail for supplying the rail 254 to the lower plate 220 and the upper plate 210.

The rail for supplying electricity 254 is installed to be fixed to the lower frame 272.

The carbon brush 252 is installed to be rotatable with the base frame 271 in contact with the rail for supplying electricity 254. The carbon brush 252 is connected to the upper flat plate 220 and the lower flat plate 210 by an electric wire (not shown) passing through the through hole 273a of the support 273.

Preferably, the sludge drying apparatus 300 includes a condensation unit 260 for condensing water vapor generated from the sludge 1.

As shown in FIG. 14, the condensation unit 260 includes an upper cover 262 installed on an upper side of the upper plate 220, and cooling water moves inside the upper cover 262. The heated steam discharged from the sludge 1 is moved upwards and then cooled by the top cover 262.

More preferably, the condensation unit 260 includes a condensate guide roof 264 installed between the upper cover 262 and the upper plate 220 to receive condensed water cooled and condensed by the cooling water and moved toward the wall. On the other hand, the wall 266 is installed to be connected to the upper cover 262 to seal the internal space in which the sludge drying apparatus 300 is installed. The condensate guide roof 264 has a high cross section and a low structure at both sides. The condensate moved to the wall 266 by the condensate guide roof 264 flows down the wall 266 toward the bottom.

Next, a method of treating sludge using the sludge drying apparatus 100 according to the first embodiment of the present invention will be described.

The sludge 1 from which some of the water is removed in the dehydration step is introduced into the cylinder member 44. The sludge 1 introduced into the cylinder member 44 is moved to the rotary gear pump 43 by the propeller member 44a, and the rotary gear pump 43 moves the sludge 1 to the coating member 42. The coating member 42 applies the sludge 1 to the lower plate 10 in a thin thickness, for example, a thickness of about 2 mm in a state where the upper plate 20 and the lower plate 10 are spaced apart from each other.

When the sludge 1 is applied to the lower plate 10, the upper and lower plate 20, 10 is circulated by the transfer unit while being heated by the heating unit 50. At this time, the upper and lower flat plates 20 and 10 and the sludge 1 are brought into close contact with each other by the weight of the upper flat plate 20. On the other hand, it is preferable to preheat the lower plate 10 and the upper plate 20 before the sludge 1 is applied.

The time for which the sludge 1 is heated may vary depending on the thickness of the sludge 1, the temperatures of the upper flat plate 20 and the lower flat plate 10.

When the upper and lower flat plates 20 and 10 have a temperature of 160 ° C., the sludge 1 has a drying time of 4.5 minutes for 2 mm, a drying time for 9 minutes for 3 mm, a drying time for 18 minutes for 4 mm, and 20 for 5 mm. Even if dried more than a minute, the center part is not dried.

On the other hand, the upper plate 20 and the lower plate 10 is heated by the heat medium oil, the heating furnace 51 burns the already completed dry sludge to heat the heat medium oil. The heated heat medium oil is supplied to the upper flat plate 20 and the lower flat plate 10 through the supply pipe 52, the upper rotating member 55a, and the connecting pipe 56, respectively. The rotating member is rotated at the same speed as the moving speed of the chain member (74). In addition, the connector 56 is made of a flexible material.

The upper plate 20 is circulated by the transfer unit, which is raised while passing through the section in which the guide unit 30 is installed. That is, the upper flat plate 20 is periodically raised by the guide unit 30 so that the water vapor can be discharged.

When the upper plate 20 is raised, water vapor discharged from the sludge 1 is discharged to the outside. When the upper plate 20 and the lower plate 10 are momentarily separated, water vapor is rapidly discharged, and when the upper plate 20 and the lower plate 10 are in close contact with each other, the heat of the upper plate 20 is sludge 1. Is passed back to. As such, the heating and steam discharge of the sludge 1 are repeated, and the number of repetitions may be continued until the sludge 1 is dried to a desired degree. The water vapor becomes condensed water by the condensation unit 60.

As such, when the sludge is completely dried through the application of the sludge, heating, and water vapor discharge, the sludge 1 is removed from the lower plate 10 using the removal member 47. The sludge 1 removed from the lower plate 10 is loaded in the sludge cylinder 49. The sludge 1 loaded in the sludge container 49 is used to heat the heat medium oil in the heating furnace 51 (renewable energy carrying out process).

In the above described embodiments in which the upper plate 20 is lowered relative to the lower plate 10, the lower plate 10 is raised or lowered relative to the upper plate 20, or the upper plate 20 and the lower plate 20 are lowered. (10) may be raised and lowered at the same time. In addition, in the above embodiments, the upper plate 20 and the lower plate 10 are heated together, but only one of the upper plate 20 and the lower plate 10 may be heated.

Since the method for treating sludge using the sludge drying apparatus 200 of the second embodiment will be apparent to those skilled in the art by the above description, description thereof will be omitted.

Meanwhile, a process of treating the sludge 1 using the sludge drying apparatus 300 according to the third embodiment of the present invention is as follows.

The sludge 1 from which some of the water is removed in the dehydration process is introduced into the tube member 44 of the supply unit 41. The sludge 1 injected into the cylinder member 44 is moved to the rotary gear pump 43 by the propeller member 44a, and the rotary gear pump 43 moves the sludge 1 to the coating member 45. The coating member 45 applies the sludge 1 to the lower flat plate 210 in a row with a predetermined thickness in a state where the upper flat plate 20 and the lower flat plate 10 are spaced apart from each other. The row sludge 1 has a predetermined interval.

After the sludge 1 is applied to the lower plate 210 and the upper plate 220 passes through the downward inclined portion 233c, the upper plate 220 is moved downwards so that the upper and lower plate plates 220 and 210 are sludge. It is spaced apart by the thickness of (1). Even after the upper plate 220 passes through the downward inclined portion 233c, the upper plate 220 and the lower plate 210 gradually move for about 5-20 seconds while the upper plate 220 passes through the auxiliary guide portion 234. In this case, the sludge 1 applied in the form of a string is pressed while being heated between the flat plates 220 and 210 and the heated water vapor is present in the space 1a because there is a space 1a between the sludge 1. It can be discharged to the outside through. After the upper plate 220 passes through the auxiliary guide part 234, the upper and lower plate plates 220 and 210 are completely in contact with each other by the load of the upper plate 220. On the other hand, the upper and lower flat plates 220 and 210 are heated by the electric energy supplied through the rail 254 and the carbon brush 252 for electricity supply.

When the upper plate 220 is raised, water vapor discharged from the sludge 1 is discharged to the outside. When the upper plate 220 and the lower plate 210 are momentarily separated, water vapor is rapidly discharged, and when the upper plate 220 and the lower plate 210 are in close contact with each other, the heat of the upper plate 220 is sludge (1). Is passed back to. As such, the heating and steam discharge of the sludge 1 are repeated, and the number of repetitions may be continued until the sludge 1 is dried to a desired degree.

The water vapor rises to the upper cover 220. The water vapor is cooled and condensed by the cooling water inside the upper cover 220 to become condensed water.

Condensate is dropped into the condensate guide roof 264, the condensate guide roof 264 guides the condensate to the wall (266). Condensate induced by the wall 266 is moved to the bottom by the wall 266.

As such, when the sludge is completely dried through the application of the sludge, heating, and water vapor discharge, the sludge 1 is removed from the lower plate 210 using the removal member 47. The sludge 1 removed from the lower plate 210 is loaded into the sludge cylinder 49. The sludge 1 loaded in the sludge container 49 may be used as renewable energy because the amount of heat discharged during combustion is large.

Meanwhile, the sludge drying apparatus 300 using the electric energy has been described above, but the sludge drying apparatus 300 may use energy discharged during incineration of the sludge 1. That is, the sludge drying apparatus 300 has a heating unit that uses heat energy generated during combustion of the sludge 1 instead of the heating unit 250 including the rail 254 and the carbon brush 252 for electricity supply. You may. Such a heating unit can be easily known to those skilled in the art from the heating unit 50 of the first embodiment.

That is, the heating unit is supplied with a heating furnace 51 for heating the heating medium oil and the heating medium oil heated from the heating furnace 51 and installed inside the through hole 271b to rotate the base frame 271. At least one of the upper plate 220 and the lower plate 210 so that the rotating member rotates at the same speed as the speed, and the heat medium oil can be supplied from the rotating member to at least one of the upper plate 220 and the lower plate 210. And a connection pipe connected to the rotating member and made of a flexible material. The heating medium oil heated in the heating furnace 51 is supplied to at least one of the upper plate 220 and the lower plate 210 through the rotating member and the connection pipe.

In the above described embodiments in which the upper plate 20, 220 is raised and lowered relative to the lower plate 10, 210, but the lower plate 10, 210 is raised relative to the upper plate 20, 220 The lower flat plate 20, 220 and the lower flat plate 10, 210 may be raised and lowered at the same time. In addition, in the above embodiments, the upper plate 20, 220 and the lower plate 10, 210 are heated together, but only one of the upper plate 20, 220 or the lower plate 10, 210 is heated. It may be heated.

On the other hand, as shown in FIG. 16, the flat plates 3 of a predetermined size are stacked vertically, and the sludge 1 is placed between the flat plates 3, and then the flat plates 3 are heated to form the sludge 1. It is also possible to dry. In this case, the lowermost flat plate 3 is moved upward by a predetermined moving mechanism (not shown) to become the uppermost flat plate 3, and sludge is applied thereon, and is adhered to the next flat plate 3, and the lowermost flat plate 3 Plates 3 above the plate 3 are sequentially slid down, and in this process, the plate 3 in close contact is spaced apart and water vapor is discharged. The sludge 1 applied between the plates 3 is dried while descending, and when the plate 3 is lowered to the bottom, the sludge 1 is moved to the top, and the dried sludge 1 is removed.

1 is a flow chart showing a sewage treatment process according to the prior art.

2 is a plan view showing a sludge drying apparatus according to a first embodiment of the present invention.

Figures 3a to 3e is a schematic view showing a process of removing the sludge after the sludge is applied and heated in the sludge drying apparatus of Figure 2, respectively.

Figures 4a to 4c is a perspective view showing that the upper plate of the sludge drying apparatus of Figure 2 is operated, respectively.

5 is a perspective view showing a supply unit provided in the sludge drying apparatus of FIG.

Figure 6 is a front view showing that the lowering of the upper plate is made by the elevating unit provided in the sludge drying apparatus of FIG.

7 is a perspective view showing a modification of the supply unit provided in the sludge drying apparatus of FIG.

8A to 8E are schematic views illustrating a process of removing sludge after being applied and heated when sludge is supplied by the supply unit of FIG. 7.

9 is a plan view showing a sludge drying apparatus according to a second embodiment of the present invention.

10 is a perspective view showing a transfer unit, a lifting unit, an upper flat plate and a lower flat plate of the sludge drying apparatus of FIG. 9;

11A to 11C are perspective views showing that the upper plate of the sludge drying apparatus of FIG. 9 is operated, respectively.

12 is a perspective view showing a sludge drying apparatus according to a third embodiment of the present invention.

Figures 13a to 13f is a perspective view showing the assembled state of each part in the sludge drying apparatus of FIG.

14 is a front view showing a condensation unit provided in the sludge drying apparatus of FIG.

15 is a flow chart showing a sludge treatment process using a sludge drying apparatus according to a first embodiment of the present invention.

16 is a schematic view showing another method of treating sludge in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

1: sludge 10, 210: lower plate

20, 220: upper flat plate 30, 233: guide part

40, 41: supply unit 50, 150, 250: heating unit

60, 260: condensation unit

100, 200, 300: sludge drying device

Claims (22)

Upper plate; Bottom plate; An elevating unit for elevating at least one of the upper plate and the lower plate to be in close contact with the other one; And, It includes; a heating unit for heating at least one of the upper plate and the lower plate, After the sludge is applied to the lower plate, the sludge drying apparatus characterized in that the sludge is heated by the heating unit in a state in which the sludge is in close contact between the upper plate and the lower plate. The method of claim 1, There are a plurality of upper and lower plates, Further comprising a transfer unit for transferring a plurality of upper and lower plates, The transfer unit is A chain member moved on the track by a drive motor; And, Sludge drying apparatus comprising a; connecting portion for connecting the chain member and the lower plate. The method of claim 1, Further comprising a transfer unit for transferring a plurality of upper and lower plates, The transfer unit is A circular base frame rotated by a drive source and having a through hole formed at a center thereof; A support installed around the through hole; And It is installed on the top of the support is rotated with the base frame, the guide plate formed with a guide hole at a predetermined interval; includes, A lower flat plate is installed around the support to support the base frame, and an upper flat plate is installed in the guide hole so that the lowering plate can be lifted up and down by the elevating unit. Sludge drying apparatus characterized in that the lifting and lowering guided by the hole. The method of claim 1, Further comprising a transfer unit for transferring a plurality of upper and lower plates, While the upper plate and the lower plate are transported by the conveying unit, one of the upper plate and the lower plate is lowered by the elevating unit, Sludge drying apparatus characterized in that the application of the sludge and the removal of the dried sludge is made while the upper and lower plates are separated by the elevating unit. The method according to claim 2 or 3, The upper and lower rollers are installed on the upper surface of the upper plate, The elevating unit has a guide part for guiding the elevating roller while the upper plate is moved by the transfer unit. Guide part, A sludge drying apparatus comprising an upward inclined portion for allowing the upper flat plate to rise and a downward inclined portion for lowering the upper flat plate when the lifting roller is moved while being guided by the guide part. The method of claim 1, A transfer unit for transferring a plurality of upper and lower plates, and a supply unit for applying sludge to the lower plate, Supply unit is An application member provided between the lower plate and the upper plate so that the sludge can be applied to the lower plate thinly with a predetermined thickness while the upper plate and the lower plate are moved apart from each other; And, Sludge drying apparatus comprising a; transfer unit for transferring the sludge to the coating member. The method of claim 1, A transfer unit for transferring a plurality of upper and lower plates, and a supply unit for applying sludge to the lower plate, Supply unit is An application member installed between the lower plate and the upper plate such that the sludge in a row form having a predetermined thickness may be discharged to the lower plate at a predetermined interval while the upper plate and the lower plate are moved apart from each other; And, Sludge drying apparatus comprising a; transfer unit for transferring the sludge to the coating member. The method of claim 7, wherein The upper and lower rollers are installed on the upper surface of the upper plate, The elevating unit has a guide part for guiding the elevating roller while the upper plate is moved by the transfer unit. Guide part, An upward inclination portion for allowing the upper flat plate to rise when the lifting roller is moved while being guided by the guide portion; A downward slope for lowering the upper flat plate; And, And an auxiliary guide part installed at a rear of the downward inclined part. The auxiliary guide part, Sludge drying apparatus characterized in that it is formed to have a gentle downward slope than the downward slope portion so that the upper flat plate is gradually lowered so that the water vapor discharged from the sludge can be discharged through the space (1a) between the sludge-type sludge . The method according to claim 6 or 7, The transfer unit, A barrel member hollow inside so that the introduced sludge can be moved downward; A plurality of wings arranged at a predetermined angle, the propeller member being rotatably installed in the hollow to move the sludge down; And And a pump having an inlet installed in communication with the lower end of the cylinder member, and a discharge port communicating with the coating member, and applying pressure to the sludge introduced through the inlet by the propeller member and discharging it through the discharge port. Drying equipment. The method of claim 9, Sludge drying apparatus, characterized in that the pump is a rotary gear pump. The method according to claim 2 or 3, Further provided with a removal member for removing the dried sludge from the lower plate, The upper plate and the lower plate are closely contacted or separated from each other by the elevating unit while being transported by the transfer unit. The removal member is a sludge drying apparatus, characterized in that installed on the lower plate at a height lower than the thickness of the dried sludge so as to separate the dried sludge from the lower plate while the upper plate and the lower plate is moved in the spaced apart state. The method according to claim 2 or 3, The heating unit is A carbon brush electrically connected to at least one of an upper plate and a lower plate; And Sludge drying apparatus comprising a; is installed to be in contact with the carbon brush, the supply rail for supplying electricity to at least one of the lower plate and the upper plate through the carbon brush. The method of claim 2, The heating unit is A heating furnace for heating the heat medium oil; A rotating member that is supplied with heated heat medium oil and installed inside the chain member circulating in an endless track, and rotates at the same speed as the moving speed of the chain member; And And a connection pipe connected to at least one of the upper flat plate and the lower flat plate and the rotating member so as to supply the heat medium oil to at least one of the upper flat plate and the lower flat plate from the rotating member. Sludge drying apparatus characterized in that the heating medium oil heated in the heating furnace is supplied to at least one of the upper plate and the lower plate through the rotating member and the connecting pipe. The method of claim 3, The heating unit is A heating furnace for heating the heat medium oil; A rotating member that receives the heated heat medium oil and is installed inside the through hole and rotates at the same speed as the rotation speed of the base frame; And Including; a connecting pipe made of a flexible material connected to at least one of the upper plate and the lower plate and the rotating member to supply the heat medium oil to at least one of the upper plate and the lower plate from the rotating member; Sludge drying apparatus characterized in that the heating medium oil heated in the heating furnace is supplied to at least one of the upper plate and the lower plate through the rotating member and the connecting pipe. The method according to claim 13 or 14, A furnace is the sludge drying apparatus, characterized in that to heat the heat medium oil by burning the sludge already dried. The method of claim 1 Sludge drying apparatus further comprises a condensation unit installed on the upper side of the upper plate to condense the water vapor generated from the heated sludge. The method of claim 16, The condensation unit It is installed on the upper side of the upper plate, and includes an upper cover in which the coolant moves, The sludge drying apparatus, characterized in that the water vapor generated by the heating unit is cooled and condensed by the cooling water. The method of claim 17, The inner space where the sludge drying device is installed is sealed by a wall installed to be connected to the upper cover, The condensation unit And a condensate inducing roof installed between the upper cover and the upper plate to receive condensed water cooled and condensed by the cooling water and moved to the wall. (a) applying sludge to the lower plate; (b) heating the sludge by heating at least one of the upper plate and the lower plate while pressing the sludge using the upper plate; And (c) removing the dried sludge; sludge treatment method comprising a. The method of claim 19, in step (b), A sludge treatment method comprising incineration of already dried sludge to heat the heat medium oil, and heating at least one of the upper plate and the lower plate using the heated heat medium oil. The method of claim 17, The water vapor generated from the heated sludge is condensed by the cooling water, the condensate condensed water vapor is sent to the water purification process. (a1) heating the plate 3 and applying the sludge 1 thinly on the upper surface of the plate 3 to a predetermined thickness; (b1) stacking the heated plate 3 on the upper surface of the sludge 1 and applying the sludge 1 to the upper surface of the heated plate 3; (c1) repeating steps (a1) and (b1) a predetermined number of times; (d1) the sludge 1 placed between the plates 3 is brought into close contact and heat-dried while the laminated plates 3 are moved downward; (e1) separating the lowest plate 3 from the stacked plates 3 from the upper plates 3 stacked thereon, and removing the sludge 1 applied to the upper surface of the lower plate 3; (f1) stacking the lowermost flat plate (3) on the sludge (1) applied to the uppermost flat plate (3).

Images