KR100625040B1 - Hot Filter Press System and Dring method of That - Google Patents

Abstract

The present invention relates to a heat transfer device of a heat filter press dewatering device and a driving method thereof, comprising: a heat filter press dewatering device for forming a sludge cake chamber; A hot water transfer loop pipe for circulating the internal circulation water with a hot water circulation pump using a heat exchanger and a hot plate as a closed path; A steam transfer tube for transferring a boiler and thermal energy of the boiler to the heat exchanger in the form of steam; It relates to a heat transfer device of a heat filter press dewatering device and a driving method thereof.

According to the present invention, there is an advantage in that a thermal filter press dewatering device for increasing thermal efficiency and increasing thermal efficiency by performing precise thermal dehydration control is provided.

Man brain plate, soleplate, sludge, sludge cake,

Description

Heat transfer device of thermal filter press dehydrator and its driving method {Hot Filter Press System and Dring method of That}

1 is an exemplary view of a heat transfer device of a heat filter press dewatering device according to the present invention.

2 is a conceptual diagram of a heat transfer apparatus of a heat filter press dewatering apparatus according to the present invention.

Figure 3 is a cross-sectional structural view of the filter press of the thermal filter press dewatering apparatus according to the present invention

Figure 4 is another embodiment of a heat transfer device of the heat filter press dewatering device according to the present invention

5 is a temperature control circuit block applied to the heat transfer device of the thermal filter press dewatering device of the present invention.

Figure 6 is a flow chart of a part of the heat transfer device of the heat filter press dewatering device of the present invention

* Explanation of symbols on main parts of drawings *

1: 1st preparation stage 2: 2nd preparation stage

3: first dewatering process 4: second dewatering process

5: heat dehydration process 10: buffer tank

50: sludge tank 51: filter cloth

52: sludge cake chamber 53: sludge through hole

60: sludge supply pump 70: temperature sensor

100: hydrothermal transfer loop pipe 110: hydrothermal circulation pump

120: hot plate 150: control unit

140: heat exchanger 200: steam transfer tube

220: boiler 225: control valve

230: preheater 300: heat filter press dewatering device

The present invention relates to a heat transfer device and a method of the heat filter press dewatering apparatus, and more particularly, a heat filter press dewatering apparatus for forming a sludge cake chamber by forming a filter cloth on the surface and slidingly moving by a pressure plate to form a sludge cake chamber; A heat exchanger for receiving internal circulating water from a buffer tank, and a heat exchanger for supplying internal circulating water to steam and a hot plate of a thermal filter press dewatering device for supplying internal circulated water heated by the heat exchanger to dehydration vapor pressure energy of a sludge cake. A hydrothermal transfer loop tube for circulating the internal circulating water with a hydrothermal circulation pump; A steam transfer pipe receiving water from the water storage tank and applying thermal energy to transfer the boiler and the thermal energy of the boiler to the heat exchanger in the form of steam; And a first valve for connecting the heat transfer device and the buffer tank of the heat filter press dewatering device to transfer heat energy to the surface of the hot plate by hot water to dehydrate the sludge in close contact with the hot plate surface. A first preparation step of operating the hot water circulation pump to supply and circulate internal circulating water to the hot water transfer loop pipe of the closed loop via the hot plate of the heat filter press and the heat exchanger; Supplying water to the boiler from an external water tank to produce steam and transferring the produced steam to the heat exchanger; When the internal circulating water temperature of the hydrothermal transfer loop pipe is increased by the second preparation step, a sludge supply pump for supplying sludge to a thermal filter press is operated to fill the sludge in the thermal filter press. A first dewatering step of dewatering the sludge supply pressure by the sludge circulation pump; A second dehydration step of dewatering the sludge by the expansion pressure of the man brain plate when the sludge injection into the thermal filter press is finished; During the first dehydration process and the second dehydration process by continuously sensing the temperature of the hydrothermal transfer loop pipe to feedback control the steam output of the boiler, to maintain the hot plate temperature of the heat filter press, which is transmitted to the hot plate A thermal dehydration process for dehydrating moisture inside the sludge with steam energy; It relates to a method of operating a thermal filter press dewatering device characterized in that configured.

Sludge produced in Korea is processed (industrial) sludge produced at industrial sites such as petrochemical, steelworks, salt and pigment processes, aqueous sludge generated at sewage treatment plants and water purification plants, and livestock such as manure, pig manure and poultry. It can be classified into three types like manure sludge.

When each of these sludges are classified and classified, there are about 50 species or more, and each of the sludges exhibits various dehydration characteristics.

The most important factor affecting dehydration is the content of organic and inorganic substances in sludge. The higher the organic content, the more difficult the dehydration of sludge.

Process sludge has a low organic content (20 wt%), so it is easy to dehydrate, but aqueous sludge and livestock manure sludge have a very high organic content (40-60 wt%).

Currently, the dehydration method developed and applied in Korea and abroad is mostly a mechanical filtration method, and the dehydration device to which it is applied includes a filter press, a belt press, a vacuum dehydrator, and a decanter.

Conventional dewatering devices, such as filter presses, belt presses, and vacuum dehydrators, are dehydration that separates solids and liquids by applying mechanical forces (vacuum pressure, pressing force, etc.) to the sludge layer. Although it is effective for the dewatering of process sludge with a high content of inorganic matter in organic / inorganic materials, there is a problem in that it is inadequate for the dewatering of the sewage sludge treatment process and livestock manure sludge with a high content of organic matter.

The reason for this is due to the pore-forming mechanism of the sludge layer and the characteristics of free and surface water distributed on the surface of the particles in the sludge.

In other words, the process sludge having a large amount of inorganic components has a lot of free water (water that can be easily dehydrated depending on the pressure) and relatively low surface water (water that is difficult to dewater due to the pressure).

In addition, if the distribution of free water is large, the formation of pores is easy, so that a capillary tube is formed well, and water is easily discharged from the cake layer.

The reason why sand drains well is because of this principle.

However, organic sludge water and sewage sludge treatment processes and livestock manure sludge have a large number of surfaces, making it difficult to form pores, making it difficult to form capillaries in the sludge layer.

However, when dewatering with a mechanical dehydrator, process sludge can produce dehydrated cakes with a water content of about 60 wt%, whereas water and sewage sludge treatment processes and livestock manure sludge produce dehydrated cakes with a water content of 80 to 90 wt%. do.

When the dehydrated cake having a high moisture content is produced as described above, there is a problem in that the transportation cost is high during the existing treatment by ocean dumping and landfill, and economic and environmental losses due to the generation of leachate are generated.

In addition, for the effective treatment of dehydrated cakes, it is important to treat them by recycling methods such as organic fertilizers, cover materials, and lightweight aggregates. For such treatment methods, there is a problem in that low moisture content dehydrated cakes must be produced.

The present inventors have developed a heat filter press dewatering apparatus to solve the above problems, and has filed a prior application of the application number 10-2002-0026903.

In accordance with the above application, the present inventors have developed an apparatus for simultaneously treating mechanical dehydration and thermal dehydration to produce a sludge cake having a low water content.

The application is to insert a hot plate having a sludge supply unit between the manbure plate of the mechanical filter press dewatering device and to apply heat energy to the hot plate using steam as a heat medium, so that dehydration by pump pressure and dehydration by steam.

However, according to the above-described application method, when the heat medium introduced into the hot plate is steam having heat energy of about 120 ° C. at a pressure of 1 kg / cm ² , the heat energy is transferred to the surface of the hot plate and the heat medium discharged is still 1 kg / cm ^2. Since the steam has a heat energy of about 112 ° C. at a pressure of, a separate condenser is required to process the discharged steam, which makes it difficult to invest and control the device. It's a big problem.

This is because the size of the hot plate is relatively small for the steam to transfer sufficient heat energy to the hot plate, and the time for passing through the internal sludge supply unit is also short.

By the way, the temperature of the sludge required for dewatering the sludge is 40 ℃ ~ 80 ℃ is sufficient, if it exceeds 80 ℃ may be rather dry due to overheating, such a small energy consumption of this degree can be said to be essential.

For the treatment of sludge, the concept of dehydration and drying must be clearly distinguished because some amount of moisture must be contained in order for the sludge to be present as a cake.

That is, the dry powder state (drying area) without moisture in the sludge may cause problems such as scattering of the powder, difficulty in transportation, and difficulty in disposal, and thus itself may be a new environmental pollution. The disposal range is extended to the area of recycling as well as the processing only in the state of the cake.

Therefore, the environmentally useful sludge dewatering cake has a great need to be precisely dehydrated water having a moisture content of less than a few minutes.

An object of the present invention is to provide a heat filter press dewatering apparatus for improving the thermal efficiency by improving the above-described problems of the present applicant.

That is, an object of the present invention is to provide a heat filter press dewatering device that focuses attention on the amount of heat required for the dewatering cake and consumes only the necessary amount of heat to precisely control the water in the sludge.

And it aims at providing the thermal filter press dehydration apparatus which reduces the energy consumption required to maintain the high temperature of a thermal medium, and recycles waste heat.

Accordingly, an object of the present invention is to provide a heat filter press dewatering device capable of producing a low moisture content dewatered cake by precisely dehydrating organic dehydrated sludge such as water and sewage sludge or livestock manure sludge.

The present invention has been made in order to solve the above problems, and in detail, a filter cloth is formed on the surface and the thermal filter press dewatering device for forming a sludge cake chamber by slidingly moved by the pressing plate to be in close contact with each other; A heat exchanger for receiving internal circulation water from a buffer tank, and a heat exchanger for supplying internal circulation water with steam and a hot plate of a thermal filter press dewatering device for supplying internal circulation water heated by the heat exchanger to dehydration steam pressure energy of a sludge cake. A hydrothermal transfer loop tube for circulating the internal circulating water with a hydrothermal circulation pump; A steam transfer pipe receiving water from the water storage tank and applying thermal energy to transfer the boiler and the thermal energy of the boiler to the heat exchanger in the form of steam; The heat transfer device of the heat filter press dewatering apparatus is configured to transfer heat energy to the surface of the hot plate by hot water to thermally dewater the sludge in close contact with the hot plate surface.

Wherein the steam transfer pipe is located between the water storage tank and the boiler, the preheater for preheating the water flowing into the boiler with the remaining heat energy provided in the heat exchanger; It is preferable to be a heat transfer device of a heat filter press dewatering device, characterized in that it further comprises.

The thermal filter press dewatering device includes a temperature sensor for sensing a temperature of internal circulating water; A control unit for generating a drive signal of the sludge supply pump and an output control signal of the boiler as a control signal according to the control temperature detected by the temperature sensor; It is preferable to be a heat transfer device of a heat filter press dewatering device, characterized in that it further comprises.

In addition, the control temperature is preferably a heat transfer device of the heat filter press dewatering device, characterized in that 80 ℃ or more.

The control temperature is particularly preferably a heat transfer device of the heat filter press dewatering device, characterized in that 95 ℃ ± 3 ℃.

Meanwhile, the present invention opens a first valve connecting the buffer tank and operates a hot water circulation pump to supply and circulate internal circulating water to a hot water transfer loop pipe of a closed loop via a hot plate of the heat filter press and a heat exchanger. Steps; Supplying water to the boiler from an external water tank to produce steam and transferring the produced steam to the heat exchanger; When the internal circulating water temperature of the hydrothermal transfer loop pipe is increased by the second preparation step, a sludge supply pump for supplying sludge to a thermal filter press is operated to fill the sludge in the thermal filter press. A first dewatering step of dewatering the sludge supply pressure by the sludge circulation pump; A second dehydration step of dewatering the sludge by the expansion pressure of the man brain plate when the sludge injection into the thermal filter press is finished; During the first dehydration process and the second dehydration process by continuously sensing the temperature of the hydrothermal transfer loop pipe to feedback control the steam output of the boiler, to maintain the hot plate temperature of the heat filter press, which is transmitted to the hot plate A thermal dehydration process for dehydrating moisture inside the sludge with steam energy; Another technical subject is a method of operating a thermal filter press dewatering apparatus, characterized in that the configuration.

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

In the following description of the present invention, if it is determined that the detailed description of the related known technology or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators.

Therefore, the definition should be made based on the contents throughout the specification for describing the present invention.

1 is an exemplary view showing a heat transfer apparatus of a heat filter press dehydration apparatus according to the present invention, FIG. 2 is a conceptual diagram of a heat transfer apparatus of the heat filter press dehydration apparatus according to the present invention, and FIG. 3 is a heat filter according to the present invention. 4 is a cross-sectional view of the filter press of the press dewatering apparatus, and FIG. 4 is another embodiment of the heat transfer apparatus of the heat filter press dewatering apparatus according to the present invention, and FIG. 5 is a heat transfer apparatus of the heat filter press dewatering apparatus of the present invention. 6 is a block diagram of a temperature control circuit to be applied.

As shown in the figure, the present invention is largely a heat-water transfer loop having a heat filter press dewatering apparatus 300, a buffer tank 10, a heat exchanger 140, a heat plate 120, and a hydrothermal circulation pump 110 as a closed path. The pipe 100, and the boiler 220 and the heat exchanger 140 is composed of a steam transfer pipe 200 as a path.

The steam transfer pipe 200 further includes a preheater 230. In addition, the steam transfer pipe 200 includes a controller 150, a control valve 225, and a temperature sensor 70.

Hereinafter, the thermal filter press dehydration apparatus 300 will be described with reference to FIGS. 1 and 3.

The thermal filter press dewatering device 300 has a filter cloth 51 is formed on the surface and the plurality of man-brain plate 310 and the hot plate 120 to form a sludge cake chamber 52 by sliding and closely contacted by the hydraulic device Is formed.

In detail, the man-brain plate 310 has a sludge through-hole 53 penetrating the front center (when the sludge is introduced by the side feeding method when the sludge-passing method is a front feeding method of the sludge feeding method, there is no sludge passing-through hole). Hereinafter, the front feeding method illustrated in FIG. 3 will be described as an example.) When the front center portion is embedded, and the manbrane plates 310 and the hot plates are brought into close contact with each other by the sliding movement, the manbrane plates The central recess of the hot plate 310 and the hot plate form the sludge cake chamber 52.

The sludge cake chamber 52 is communicated with each other by the sludge through hole 53, and the sludge through hole 53 is connected to the sludge tank 50 by a sludge supply pump and valves connected thereto. It is connected to communicate the sludge cake chamber 52 and the sludge tank 50.

The sludge is pumped and injected from the sludge tank 50 into the sludge cake chamber 52 by the sludge supply pump 60 and the valves 61 interlocked with the sludge supply pump 60.

In addition, a filter cloth 51 is attached to each of the man brain plate 310 and the hot plate, and the sludge supplied from the sludge supply pump 60 is filled in the sludge cake chamber 52 and is primarily The filtrate is filtered by the filter cloth 51 covered by the brain plate 310 and the hot plate 120 (hereinafter referred to as 'primary dehydration process (3)').

After the supply of the sludge is completed (that is, after the first dehydration process (3)), by supplying high pressure water or air (7 ~ 15kgf / cm2) to the manbrane plate 310 (Membrane Plate) Inflating the 310, the volume of the sludge cake chamber 52 is reduced while the secondary dewatering process 4 for dewatering the sludge at the expansion pressure of the man brain plate 310 is performed.

Since the primary dehydration process (3) and the secondary dehydration process (4) is the same as the conventional man brain filter press dewatering process of mechanically dewatering the sludge, further detailed description of the additional process will be omitted.

In the present invention, in addition to the primary dehydration process (3) and the secondary dehydration process (4), a thermal dehydration process (5) such as the present inventor's prior application 10-2002-0026903 is added.

The thermal dehydration process (5) of the present invention is a hot plate inserted between the manbure plate 310 during the first dehydration by the sludge supply pressure and the second dewatering by the expansion pressure of the man brain plate 310 It is a dehydration process which supplies thermal energy of 40-80 degreeC to 120 and promotes separation of particle | grains and water by vapor pressure.

That is, the thermal dehydration step 5 refers to a dehydration step of generating a vapor pressure by applying heat energy to moisture contained in the sludge particles, and discharging water inside the sludge particles by the vapor pressure, as described above. As dehydration proceeds due to the vapor pressure at, the amount of particles per unit volume in the sludge is increased to increase the amount of sludge supplied in the volume of the same sludge cake chamber 52.

Hereinafter, the present invention will be described with reference to FIGS. 1 and 2, while describing the thermal dehydration process 5.

The steam transfer pipe 200 of the present invention connects the heat exchanger 140 and the boiler 220 for producing the heat chain steam provided to the heat exchanger 140 and the external water tank 210 (or the water storage tank). .

As shown in FIG. 2, the boiler 220 receives steam from an external water tank 210 to produce water to transfer thermal energy, and the steam is transferred to the heat exchanger 140 to supply hot water. Transfer heat energy to the transfer loop tube (100).

That is, the heat exchanger 140 is a device for transferring the heat energy produced in the form of steam in the steam transfer pipe 200 to the internal circulating water of the hydrothermal transfer loop pipe 100.

The hot water transfer loop tube 100 of the present invention is a closed loop tube body connected to the hot plate 120 and the heat exchanger 140.

The hot water transfer loop pipe 100 includes a hot water circulation pump 110 to circulate the internal circulation water.

The hot water circulation pump 110 is controlled with circulation and supplemental control valves interlocked with the hot water circulation pump 110, and is connected to the buffer tank 10 so as to be internally circulated in the hot water transfer loop pipe 100 when preparing for operation of the present invention. Fill the water and replenish the internal circulating water exhausted by evaporation during operation.

Summarizing the above hydrothermal transfer loop pipe 100, the internal circulation water is circulated by the hydrothermal circulation pump 110, and the heat exchanger 140 and the heat exchanger 140 heat the internal circulation water with steam. The hot plate 120 of the heat filter press dewatering device for supplying the heated internal circulating water to the dehydration vapor pressure energy of the sludge cake is used as a closed path.

The steam transfer pipe 200 and the hydrothermal transfer loop pipe 100 are ultimately a heat transfer path for transferring heat energy to the hot plate 120 of the heat filter press dehydrator, as shown in FIG. The hot water path (internal circulating water) and the hot water supplied from the heat exchanger 140 are transferred to the hot plate 120, and the hot plate 120 is transferred to the sludge 80.

The heat energy transferred from the hot plate 120 naturally moves through the filter cloth 51 into the sludge (inside of the molecular microview point) to raise the sludge internal temperature, thereby allowing the pore water and the surface attached to the capillary inside the sludge. As the water evaporates, an evaporation pressure is formed, which causes the filtrate remaining in the sludge capillary to be discharged out of the sludge.

In addition, by increasing the temperature inside the sludge, the viscosity of the filtrate is lowered, the fluidity of the filtrate is improved and the discharge friction of the filtrate is eliminated, thereby accelerating the discharge of the filtrate.

On the other hand, the present invention is notable that the heat medium for supplying heat to the hot plate 20 is water (thermal water), the heat source to apply heat energy to the water is steam.

That is, in the present invention, as shown in FIGS. 1 and 2, heat energy of steam is transferred to water (internal circulating water), and heat energy of water is transferred to the hot plate 20.

Such a structure of the present invention has a very important meaning in order not to dry the sludge but only dehydration treatment.

Because, in order to dehydrate the sludge rather than drying, the temperature of the sludge should be between 40 ℃ ~ 80 ℃, if the steam is used as a direct heat medium, the sludge temperature may be more than 80 ℃ to dry the sludge.

However, when water is used as a heat medium as in the present invention, the heat required to maintain the temperature at which the sludge generates the vapor pressure is applied, as well as there is no phase change of the heat medium due to the temperature drop. When the heat energy is applied again to raise the temperature, the efficiency becomes large.

In detail, when water of 95 ° C. is introduced into the inlet of the hot plate 20 at a pressure of ¹ Kg / cm ² , heat is consumed in the hot plate 20, and water coming out of the outlet is about 92 ° C. at a pressure of about 1 Kg / cm ² . Since, in the heat exchanger 140, the steam only needs to provide a temperature rise heat energy of about 3 ℃.

Therefore, the heat energy consumed in the sludge is sufficiently provided even if the phase of the heat medium is water, and when the heat medium is water, the phase of the incoming heat medium and the discharge heat medium is the same, so that a condenser is unnecessary unlike when directly providing steam.

In addition, it is necessary to raise the temperature of the steam up to 120 ° C. and the temperature of the water up to 95 ° C., as in the conventional method, shows a large difference in the amount of energy consumed, thereby greatly saving energy.

Meanwhile, the steam transfer pipe 200 of the present invention further includes a preheater 230 for preheating the external supply water supplied from the external water tank 210 as shown in FIG. 4.

In the steam transfer pipe 200, the external supply water is phase-changed into steam in the boiler 220, and the steam transfers heat energy to the hot water transfer pipe 30 in the heat exchanger 140. Since the heat is about 3 ℃ is enough as described above, the waste heat passing through the heat exchanger 140 is used to preheat the external supply water flowing from the external water tank 210 to consume the energy consumed in the boiler 220 Save.

Hereinafter, a method for operating the thermal filter press dewatering apparatus, which is another technical subject of the present invention, will be described.

In the present invention, in order to supply heat to the sludge layer in the sludge cake chamber 52, the temperature of the hot water supplied to the hot plate 120 should be 80 ° C. or higher, and preferably about 95 ° C.

In order to supply such heat, the present invention primarily supplies steam produced from the boiler 220 to the heat exchanger 140, and the heat exchanger 140 produces hot water to supply the hot plate 120. The hot plate 120 is a closed loop device that transfers the heat transferred to the sludge layer and transfers the recovered coolant back to the heat exchanger 140.

In the existing thermal dehydrator, steam generated from the boiler 220 is directly supplied to the hot plate 120, thereby discharging condensed water (which may require a separate condenser) from the hot plate 120 to water by cooling. The heat loss was excessive and there was a problem that the produced sludge is dried.

However, according to the present invention, the cooling water (about 75 ° C.) recovered from the hot plate 120 according to the use of hot water has no phase change and minimizes heat loss as the remaining heat energy can be immediately recycled.

In the method of the present invention for performing this, the first preparation step 1, the second preparation step 2, the first dehydration process 3, the second dehydration process 4, and the thermal dehydration are largely performed as shown in FIG. It consists of a process (5).

The first preparation step 1 controls the valve 111 connecting the buffer tank 10 and operates the hot water circulation pump 110 to pass through the hot plate 120 and the heat exchanger 140 of the thermal filter press. Supplying and circulating internal circulating water to the hydrothermal transfer loop pipe 100 of the closed loop.

The second preparation step (2) is a step of supplying water to the boiler 220 from an external water tank to produce steam, and the produced steam is transferred to the heat exchanger (140).

Initial operation while controlling the hot water circulation pump 110 in the first preparation step (1) and the second preparation step (2) to circulate the internal circulating water of the temperature rise in the hot plate 120 and the heat exchanger (140) Preheat the temperature of the heating plate 120 to the required temperature (qualified control temperature).

In the first dehydration process (3) of the present invention, when the internal circulating water temperature of the hydrothermal transfer loop pipe (100) is increased by the second preparation step (2), the controller 150 as shown in FIG. Detects this and activates the sludge supply pump 240 to supply the sludge 80 to the thermal filter press, while filling the sludge in the thermal filter press to the sludge supply pressure by the sludge supply pump 60. It is a process to dehydrate.

That is, while steam is supplied from the boiler 220 to the heat exchanger 140 in the second preparation step 2, the hot water continues to circulate between the heat exchanger 140 and the hot plate 120, where the hot plate 120 is provided. When the inlet temperature of the temperature reaches the specified temperature (for example, when the experimental optimum temperature of 95 ℃ of the present invention), the control signal is automatically transmitted to the sludge supply pump 240 and the control valve linked to the heat filter Allow sludge to be supplied to the press dehydrator.

According to the present invention, the controller 150 for the control is provided separately, and the controller 150 detects the hot water flowing into the hot plate when the hot water temperature of the hot plate 120 reaches a proper control temperature. When the temperature reaches 95 ° C.), the controller 150 is programmed and set so that the control signal of the discharge valve linked to the drive of the sludge supply pump 60 is generated.

When the sludge supply pump 60 is driven by the control unit 150, the sludge cake chamber 52 of the thermal filter press is filled with sludge and primary dewatering of the sludge by the supply pressure proceeds.

In the second dehydration process (4) of the present invention, when the sludge injection into the thermal filter press is completed, the high pressure water or air (7-15 Kgf / cm2) is supplied to the man brain plate 310 (Membrane Plate), and the man brain plate is supplied. 310 is expanded, and the sludge is dehydrated by such expansion pressure.

The first dehydration process 3 and the second dehydration process 4 except for the control of the controller 150 are the same as the conventional mechanical dehydration process, and thus detailed description thereof will be omitted.

Referring to FIG. 6, the thermal dehydration process of the present invention continuously detects the temperature of the hydrothermal transfer loop pipe 100 during the first dehydration process 3 and the second dehydration process 4. By controlling the steam output of the 220, the temperature of the hot plate 120 of the heat filter press is maintained at an appropriate control temperature (for example, 95 ° C), and the moisture inside the sludge by the heat energy transmitted to the hot plate 120. Is a process of dehydrating the vapor pressure.

In detail, the temperature of the hot water passing through the hot plate 120 is drastically reduced as the sludge is supplied to the heat dehydrator, so that the feedback of the hot plate 120 is controlled to maintain the proper temperature. The feedback control is provided with a temperature sensor 70 for sensing the temperature of the hot water flowing into the hot plate 120 of the hot water transfer loop tube 100, the temperature signal detected by the temperature sensor 70 When input to the controller 150, the controller 150 applies a control signal to the control valve 225 provided at the steam output terminal of the boiler 220, by adjusting the steam output of the boiler 220 according to the temperature At the same time, maintain a certain level of control temperature.

On the other hand, as described above, the control temperature of a certain level becomes an important factor for the quality of the sludge cake produced and the appropriate energy consumption, etc., the first dehydration process (3) and heat of the hydrothermal transfer loop pipe 100 in the present invention The control temperature of the dehydration step (5) is preferably at least 80 ℃, more preferably the present invention is characterized in that the control temperature is particularly 95 ℃ ± 3 ℃.

The sludge temperature necessary for dewatering the sludge (that is, sufficient temperature necessary for generating steam pressure inside the sludge) is 40 ° C. to 80 ° C., and if it exceeds 80 ° C., the drying may occur due to overheating. In order to precisely control the degree of thermal energy, it is most suitable to use hot water as a fruit.

Therefore, in order to maintain the sludge temperature as described above, the control temperature of the internal circulating water flowing into the hot plate is preferably 80 ° C. or higher, and precisely 95 ° C. ± 3 ° C. to maintain the proper sludge temperature.

The above sludge dewatering treatment temperature is for generating an appropriate internal vapor pressure without drying the sludge.

In other words, in the treatment of sludge, the concept of dehydration and drying should be clearly distinguished, but in order to exist in the state of a recyclable cake, sludge needs to be treated in a dehydration area containing a certain amount of water, and the sludge cake has no moisture. The treatment of the drying area produced in the dry powder state causes problems such as scattering of the powder, difficulty in transportation, and difficulty in disposal, so that the sludge powder itself is not only a new environmental pollution, but also a new waste treatment target. Care must be taken as this must be released.

Therefore, sludge generated from filtration of sewage should be treated in a solid state containing water, that is, sludge cake, as well as its disposal range is extended to the area of recycling, so that sludge is dehydrated but not dried. The most important thing is the control of the temperature applied to the sludge during thermal dehydration.

In addition, the selection of the fruit to transfer the heat energy for the control of the temperature is also very important, the present invention transfers the heat energy to the hot plate 120 using the hot water as described above is applied to the hot plate 120 Provided is a method of maintaining the heat of a heat filter press dewatering device for producing an ideal sludge cake and a driving method thereof by maintaining the temperature of hot water at an appropriate control temperature.

Compared with the mechanical apparatus of the same scale, the thermal dehydration step 5 of the present invention has a large amount of particles per unit volume, so that the amount of sludge supplied increases and the treatment capacity increases, which is converted into a dehydration rate.

Specifically, the unit of dehydration rate is DS kg / m2 · hr, which means the unit filtration area and the amount of solids (DS; dry solids) treated per unit time during dehydration. Increasing means that the rate of dehydration increases.

Experiments show that the dehydration rate is improved by about 30% compared to the existing process, which means that the amount of sludge supplied into the room per unit time and unit area is about 30% higher than that of the existing process.

In the case of thermal dehydration, heat is supplied from the hot plate, unlike the conventional process, even when the secondary dehydration process proceeds. Accordingly, the filtrate is easily discharged from the pore layer formed in the cake layer of the sludge. It can be discharged, it is possible to obtain a low water content dewatering cake compared to the conventional mechanical dewatering method.

In the water content of the sludge cake, a dehydration cake having a water content of about 75 wt% can be obtained by the conventional mechanical dehydration method, while in the case of thermal dehydration, a dehydration cake of about 50 wt% can be obtained.

Converting this to a total volume basis can reduce the amount of cake produced to about 1/2, which is economical in terms of production of sludge cake to be treated.

In the above description of the present invention, if the amount of the internal circulating water is reduced by evaporation as various valves or dehydration processes are attached to the hot water transfer loop pipe or the steam transfer pipe through which the internal circulating water flows, Descriptions of well-known technologies, such as sensing and supplying from the buffer tank, will be briefly or omitted, and the description of the well-known technologies is not intended to limit the technical scope of the present invention.

According to the present invention described above, there is an advantage that the above-described problem of the present application of the present inventors is improved to provide a heat filter press dewatering device for increasing thermal efficiency.

In addition, there is an advantage that a heat filter press dewatering device is provided which increases the thermal efficiency by focusing attention on the amount of heat required for the dehydration cake and performing precise heat consumption control that consumes only the required amount of heat.

In addition, according to the present invention, there is an advantage that a heat filter press dewatering apparatus capable of producing a low moisture content dewatering cake having a water content of 60 wt% by dewatering organically dehydrated sludge such as water and sewage sludge or livestock manure sludge is provided.                     

In addition, according to the present invention, a low water content organic dehydrated cake that can be recycled by various methods such as farmland cover material, organic fertilizer, light weight materials, etc. is produced, and can be removed from ocean dumping and landfill, which is a conventional method for treating dehydrated cake, and thus economical and environmental There is an advantage that a hydrothermal filter press dehydration apparatus is provided that can achieve an effective effect.

Claims (6)

A heat filter press dewatering device for forming a sludge cake chamber by forming a filter cloth on the surface and slidingly moving by the pressing plate to be in close contact with each other; A heat exchanger for receiving internal circulating water from a buffer tank, and a heat exchanger for supplying internal circulating water to steam and a hot plate of a thermal filter press dewatering device for supplying internal circulated water heated by the heat exchanger to dehydration vapor pressure energy of a sludge cake. A hydrothermal transfer loop tube for circulating the internal circulating water with a hydrothermal circulation pump; A steam transfer pipe receiving water from the water storage tank and applying thermal energy to transfer the boiler and the thermal energy of the boiler to the heat exchanger in the form of steam; Composed The heat transfer device of the heat filter press dewatering device characterized in that the heat energy is transferred to the surface of the hot plate by hot water to dewater the sludge in close contact with the hot plate surface. The method of claim 1 wherein the steam transfer pipe A preheater located between the water tank and the boiler, the preheater preheating the water flowing into the boiler with the residual heat energy remaining in the heat exchanger; The heat transfer device of the heat filter press dewatering device characterized in that it further comprises. According to claim 1, wherein the thermal filter press dewatering device A temperature sensor for sensing the temperature of the internal circulating water; A control unit for generating a drive signal of the sludge supply pump and an output control signal of the boiler as a control signal according to the control temperature detected by the temperature sensor; The heat transfer device of the heat filter press dewatering device characterized in that it further comprises. The method of claim 3 wherein the control temperature is Heat transfer device of the heat filter press dewatering device, characterized in that the 80 ℃ or more. The method of claim 4 wherein the control temperature is In particular, the heat transfer device of the heat filter press dewatering device, characterized in that 95 ℃ ± 3 ℃. Opening a first valve connecting the buffer tank and operating a hot water circulation pump to supply and circulate internal circulating water to a hot water transfer loop tube of a closed loop via a hot plate of the heat filter press and a heat exchanger; Supplying water to the boiler from an external water tank to produce steam and transferring the produced steam to the heat exchanger; When the internal circulating water temperature of the hydrothermal transfer loop pipe is increased by the second preparation step, a sludge supply pump for supplying sludge to a thermal filter press is operated to fill the sludge in the thermal filter press. A first dewatering step of dewatering the sludge supply pressure by the sludge circulation pump; A second dehydration step of dewatering the sludge by the expansion pressure of the man brain plate when the sludge injection into the thermal filter press is finished; During the first dehydration process and the second dehydration process by continuously sensing the temperature of the hydrothermal transfer loop pipe to feedback control the steam output of the boiler, to maintain the hot plate temperature of the heat filter press, which is transmitted to the hot plate A thermal dehydration process for dehydrating moisture inside the sludge with steam energy; Operation method of the thermal filter press dewatering device, characterized in that configured.

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