JP7416876B2 - Sludge treatment method - Google Patents

Description

The present invention relates to a sludge treatment system and a sludge treatment method, and relates to, for example, water treatment or sewage treatment using a flocculant, and technology for flocculation mixing or sludge treatment in the field of industrial wastewater.

Patent Document 1 and Patent Document 2 disclose that the water content of dehydrated sludge from a screw press dehydrator is measured with a moisture meter, and the back pressure and screw rotation speed are adjusted so that the water content is below a predetermined value. A sludge treatment system is shown that prioritizes backpressure adjustment. Patent Document 3 discloses that flocs are imaged with a stock solution supply pipe that supplies a fixed amount of stock solution to a dehydrator, and a flocculant is added so that the average analysis area of the imaged flocks falls within a predetermined standard area range. A flocculant injection control method for controlling rate and agitation number is presented. Non-Patent Document 1 discloses a hybrid press-fitting screw press that employs a hydrophilic screen for the concentration section screen of a dehydrator.

Patent No. 5716049 Patent No. 5989819 Patent No. 4238983

Inuzuka, and 3 others, “Example of application of hydrophilic screen in hybrid press-fitting screw press”, 55th Sewerage Research Conference, N-10-1-6

Generally, sludge treatment systems are often operated based on the personal judgment of skilled engineers who fully understand the conditions of facilities and equipment. However, in recent years, due to social factors such as an aging population and a shortage of the working population, there has been a shortage of engineers, making it difficult to pass on skills. Therefore, automation of the sludge treatment system is desired. In this case, it is conceivable to achieve local automation using, for example, the techniques disclosed in Patent Documents 1 to 3.

However, methods using moisture meters such as those disclosed in Patent Documents 1 and 2 may not provide sufficient accuracy, and furthermore, it is difficult to control not only the moisture content but also the SS (Suspended Solids) recovery rate. is desired. Furthermore, in the method using a camera as in Patent Document 3, accurate evaluation becomes difficult if sludge adheres to the measuring section, so frequent maintenance may be required. Furthermore, even if the techniques disclosed in Patent Documents 1 to 3 are used, a certain amount of personnel is still required for some processes, and there is a fear that the problem of lack of engineers and the problem of technology inheritance cannot be sufficiently alleviated.

The present invention has been made in view of the above, and one of its purposes is to provide a sludge treatment system and a sludge treatment method that can alleviate the problem of lack of technical personnel and technology inheritance. be.

The above and other objects and novel features of the present invention will become apparent from the description of this specification and the accompanying drawings.

A brief overview of typical embodiments of the invention disclosed in this application is as follows.

A sludge treatment system according to one embodiment includes a coagulation mixer, a first flow meter and a first concentration meter, a sludge dehydrator, a second flow meter and a second concentration meter, a control device, has. The flocculation-mixing device is supplied with sludge to be treated generated in a water treatment system, and generates flocs by mixing a flocculant with the sludge to be treated. The first flowmeter and the first concentration meter respectively measure the flow rate and concentration of the sludge to be treated that is supplied to the coagulation-mixing device. A sludge dehydrator separates and removes water from coagulated flocs to produce a dehydrated cake with a reduced water content, and discharges a dehydrated filtrate corresponding to the water. The second flowmeter and second concentration meter measure the flow rate and SS concentration of the dehydrated filtrate, respectively. The control device calculates the moisture content of the dehydrated cake based on the measured values of the first flow meter and the first concentration meter, and the measured values of the second flow meter and the second concentration meter.

In a typical sludge treatment system according to the present invention, sludge to be treated generated in a water treatment system is supplied, and the sludge to be treated is supplied to a coagulation-mixing device that generates coagulated flocs by mixing a flocculant with the sludge to be treated, and a coagulation-mixing device. A first flow meter and a first concentration meter each measure the flow rate and concentration of the sludge to be treated, and a dehydrated cake with a reduced moisture content is generated by separating and removing moisture from the coagulated flocs. a sludge dehydrator that discharges the dehydrated filtrate; a second flow meter and a second concentration meter that respectively measure the flow rate and SS concentration of the dehydrated filtrate; and the measured values of the first flow meter and the first concentration meter. , and a control device that calculates the moisture content of the dehydrated cake based on the measured values of the second flowmeter and the second concentration meter.

In addition, this system further includes a sludge concentration trough that is installed between the coagulation-mixing device and the sludge dehydrator, and generates concentrated coagulated flocs by increasing the sludge concentration of the coagulated flocs generated by the coagulation-mixing device, The sludge thickening trough consists of an upper bottom, a screen installed at an angle of 30 to 70° to the horizontal plane, which separates and discharges moisture from the transported coagulated flocs, and a lower bottom, which contains the thickened flocs discharged by the screen. It is preferable to have a bottom plate for mixing the trough separated liquid with the dewatered filtrate of the sludge dewatering machine. Furthermore, this sludge thickening trough design is effective not only in the typical sludge treatment system described above but also in a wide range of devices ``installed between the flocculation mixer and the sludge dehydrator''. In addition, the screen has a plurality of screen areas having different widths of water discharge ports, and the width of the screen area on the coagulation-mixing device side is larger than the width of the screen area on the sludge dehydrator side. Larger is desirable. Further, the screen is preferably treated to be water repellent or water and oil repellent.

Here, in addition to the screen and other structural members constituting the sludge concentration trough, there are places that come into contact with the flocculated flocs or the sludge to be treated, such as the inner surface of the flocculation mixing tank, the stirring shaft of the stirring device, the stirring propeller, and the flocculated flocs of the dehydrator. The supply section, screw, screen, back pressure plate section, dewatering filtrate trough, etc. are treated with water-repellent or water- and oil-repellent treatment to prevent the adhesion of flocculated flocs and supply sludge to the supply section, screw, screen, back pressure plate section, dewatering filtrate trough, etc., so that the automatic flow during stop flow is treated. It becomes possible to significantly reduce cleaning work.

The surface treatment of the coagulated flocs and the sludge to be treated includes painting metal, coating metal, fluorine-based and/or silicone-based water repellent treatment, or vapor deposition. The material itself, such as the silicone resin, may be changed, and as long as it has a water-repellent or water- and oil-repellent effect, the processing method and material are not limited. For example, silicone-based materials include those with methyl groups oriented in the side chains of the siloxane structure, and fluorine-based materials include PTFE, PFA, and FEP, which have an oil-burning effect in addition to water repellency, such as industrial wastewater containing oil. It is effective for applications such as

Furthermore, the sludge treatment system of the present invention has a coagulation floc measurement device that measures the size of the coagulation flocs generated in the coagulation-mixing device, and the coagulation-floc measurement device transmits sound waves into the coagulation-mixing device to prevent coagulation and mixing. It is effective to have an acoustic transceiver that receives reflected waves from the agglomerated flocs in the device, and an acoustic measuring device that performs signal processing on the reflected waves received by the acoustic transceiver, and this method of detecting sound waves is effective. is effective not only for the above-mentioned typical sludge treatment systems.

On the other hand, in a typical sludge treatment method according to the present invention, a coagulation mixing device receives the sludge to be treated generated in a water treatment system, mixes a flocculant into the sludge to be treated, and stirs it at a predetermined stirring intensity. A coagulation-mixing step in which coagulated flocs are produced by this process, and a sludge dehydrator separates and removes moisture from the coagulated flocs to produce a dehydrated cake with a reduced moisture content, which is stored in a hopper and is then stored in a hopper to produce a dehydrated cake that is equivalent to the moisture content. and a dehydration step in which the dewatered filtrate is discharged, and the dewatering step includes a step in which a predetermined measuring device measures the flow rate and concentration of the sludge to be treated that is supplied to the coagulation mixing tank, and the flow rate and SS concentration of the dewatered filtrate. In step 1, the control device calculates the moisture content of the dehydrated cake based on the measured value in the first step, compares the moisture content with a predetermined moisture content reference value, and determines whether the moisture content is the moisture content reference value. The method is characterized in that it has a second step of changing the operating conditions of the sludge dehydrator if the conditions are not satisfied.

In the sludge treatment method of the present invention, the coagulation mixing step includes a third step in which the coagulation floc measuring device measures the size of the coagulated flocs, and the control device compares the size of the coagulated flocs with a predetermined size reference value. However, it may also include a fourth step of changing at least one of the supply amount of the sludge to be treated, the supply amount of the flocculant, and the stirring intensity when the size of the flocs does not meet the size standard value. It is valid. Note that, depending on the case, the fourth step may be performed before the second step.

Furthermore, in the sludge treatment method of the present invention, in the dewatering step, the control device further calculates the SS recovery rate based on the measured value of the first step, and compares the SS recovery rate with a predetermined recovery rate reference value. In comparison, it is also effective to have a fifth step of changing the operating conditions of the sludge dehydrator when the SS recovery rate does not meet the recovery rate reference value.

In addition, in the sludge treatment method of the present invention, the dewatering step includes a sixth step in which the weight measuring device measures the weight of the dehydrated cake stored in the hopper; Compare the weight of the dehydrated cake measured with a predetermined weight standard value, and when the weight of the dehydrated cake meets the weight standard value, the automatic cleaning device installed in the coagulation mixer or sludge dewatering machine starts cleaning. It is also effective to have a cleaning process that issues instructions.

Further, in the sludge treatment method of the present invention, the sludge dewatering machine is a screw press type device including a screw and a dewatering cake outlet from which the dehydrated cake is discharged, and the control device is configured to perform sludge dewatering in the second step. When changing the operating conditions of the machine, it is also effective to change at least one of the rotational speed of the screw or the opening area of the dehydrated cake outlet.

As described above, the present invention ultimately aims at saving labor in dehydration process management, and the above-mentioned systems or processing methods may be combined as appropriate.

Although the term sludge is used in this specification, the object of the present invention is not limited to sludge, but also slurry, such as slurry flowing in food factories or chemical factory processes, or slurry of industrial waste. It also includes liquids and liquids that contain solids.

According to the sludge treatment system of the embodiment, it is possible not only to operate the system stably, but also to alleviate the problem of lack of engineers or technology inheritance.

1 is a schematic diagram showing an example of the configuration of a sludge treatment system and an example of processing contents of a sludge treatment method according to an embodiment of the present invention. FIG. 2 is a flow diagram showing an example of detailed processing contents of a control device in the sludge treatment system of FIG. 1. FIG. FIG. 2 is a flow diagram showing an example of detailed processing contents of a control device in the sludge treatment system of FIG. 1. FIG. FIG. 2 is a diagram showing a detailed arrangement example of the sludge thickening trough in FIG. 1. FIG. (a), (b), and (c) are diagrams showing detailed configuration examples of the sludge thickening trough in FIG. 1. FIG. It is a flowchart which shows an example of the operation method in the sludge treatment system which is a comparative example of this invention.

Hereinafter, embodiments of the present invention will be described in detail based on the drawings. In addition, in all the figures for explaining the embodiment, the same members are given the same reference numerals in principle, and repeated explanations thereof will be omitted.

《Overview of sludge treatment system and sludge treatment method》
FIG. 1 is a schematic diagram showing an example of the configuration of a sludge treatment system and an example of processing contents of a sludge treatment method according to an embodiment of the present invention. In general, sludge generated in a water treatment system is concentrated by gravity and then, if necessary, subjected to a sludge digestion process, stored in a sludge storage tank as sludge to be treated A, and then supplied to the sludge treatment system shown in FIG. 1. The sludge treatment system shown in FIG. 1 generates coagulated flocs C in the coagulation and mixing process, and then reduces the volume to dehydrated cake G in the dehydration process and transports it outside the site. The carried out dehydrated cake G is then disposed of as waste or recycled as a material such as compost or cement material.

Moreover, in the example of FIG. 1, a concentration process is provided between the coagulation-mixing process and the dewatering process, in which the sludge concentration of the coagulated flocs C is increased to produce concentrated coagulated flocs. The coagulation-mixing process is performed by the coagulation-mixing device 4, the concentration process is performed by the sludge concentration trough 6, and the dewatering process is performed by the sludge dehydrator 7.

First, the aggregation and mixing step will be explained. The treated sludge supply pump P1 controls the supply amount of the treated sludge A, and supplies the treated sludge A with the controlled supply amount to the coagulation-mixing device 4. At this time, the flow meter SF1 and the concentration meter SD1 are in-line for supplying the sludge A to be treated to the coagulation-mixing device 4, and measure the flow rate and concentration of the sludge A to be treated, respectively. The flocculating mixer 4 mixes the flocculant B into the sludge A to be treated, and forms flocs C by stirring at a predetermined stirring intensity. At this time, the flocculant supply pump P2 controls the amount of flocculant B stored in the flocculant tank 2, and supplies the flocculant B with the controlled amount to the downstream side of the flow meter SF1 and the concentration meter SD1. It can be added indirectly through the piping line or directly to the coagulation mixer 4.

In this example, the amount of flocculant B added is measured by the flowmeter SF2, and is used to control the flocculant supply pump P2 via the control device 11. However, as long as it has been confirmed in advance that the addition amount can be controlled with high precision by the flocculant supply pump P2, the installation of the flow meter SF2 is not particularly concerned. Considering the mixing of the sludge A to be treated and the flocculant B, it is desirable to supply the sludge in a pipe, but as long as mixing in the flocculating mixer 4 is possible, the position of addition is not particularly limited. Note that the measured values of the flowmeter SF1, the concentration meter SD1, and the flowmeter SF2 are each sent to the control device 11.

As flocculant B, polymer flocculants are generally used in sludge dewatering applications, but in some cases, they are used in combination with inorganic flocculants such as polyiron, and organic and inorganic two-part chemicals are used. It may also be a note. Further, the number of additive chemicals is not particularly limited as long as the agglomerated flocs C can be sufficiently formed. The aggregation-mixing device 4 includes a coagulation-mixing tank 41 and a stirring device 42 including a drive device M1. The drive device M1 controls the stirring intensity of the stirring device 42. The coagulation-mixing device 4 mixes the sludge A to be treated to which the coagulant B has been added using the stirring device 42 in the coagulation-mixing tank 41 to generate coagulated floc-generated water D containing coagulated flocs C.

Here, the size of the aggregated flocs C is measured by the aggregated floc measuring device 5. The aggregated floc measuring device 5 includes an acoustic transceiver 52 and an acoustic measuring device 51. The acoustic transmitter/receiver 52 is installed under the water surface of the flocculation mixing tank 41, transmits sound waves into the flocculation mixing tank 41, and receives reflected waves from the flocs C in the flocculation mixing tank 41. The acoustic measurement device 51 performs signal processing on the reflected waves received by the acoustic transceiver 52. For example, the acoustic measurement device 51 generates image data of the aggregated flocs C based on the intensity, delay time, phase, etc. of the reflected waves. The control device 11 detects the floc size, floc density, etc. by performing image processing on the image data of the agglomerated flocs C.

Next, the concentration step will be explained. The floc-produced water D generated in the coagulation-mixing device 4 overflows in the coagulation-mixing tank 41 and is supplied to the sludge concentration trough 6 installed in an inclined state. The sludge concentration trough 6 is equipped with a screen 62, and by separating water from the floc-generated water D using the screen 62, a concentrated floc with increased sludge concentration of the flocculated floc C is generated, and the generated floc is transferred to the sludge dehydrator 7. do. On the other hand, the sludge concentration trough 6 supplies the separated concentrated trough separated liquid E from the screen 62 to the dewatered filtrate trough 74 via the concentrated trough separated liquid piping 61.

Next, the dehydration process will be explained. The sludge dehydrator 7 includes a screw 73, a drive device M2 that rotationally drives the screw 73, a screen 72, a dewatered filtrate trough 74, and a back pressure section clearance adjustment device 8. The back pressure section clearance adjustment device 8 includes a back pressure plate 81, a displacement sensor 82, a compressor 83, a solenoid valve 84, and an air cylinder 85. Generally speaking, the sludge dehydrator 7 separates and removes water from concentrated flocs C (concentrated flocs) to generate a dehydrated cake G with a reduced moisture content, and then stores it in a hopper 101. , the dehydrator filtrate F corresponding to water is discharged through the screen 72 into the dehydrator filtrate trough 74 .

Specifically, the concentrated flocs transferred to the sludge dewatering machine 7 are transferred to the side opposite to the sludge supply side by a screw 73 that is rotationally driven by a drive device M2, and are consolidated by outlet resistance by a back pressure plate 81. . Thereby, the concentrated flocs are separated into a dehydrator filtrate F and a dehydrated cake G through the screen 72. At this time, the back pressure part clearance adjustment device 8 adjusts the position of the back pressure plate 81 via the solenoid valve 84 and the air cylinder 85 based on the compressed air generated by the compressor 83, so that the dehydrated cake G is discharged. Adjust the opening area of the dehydrated cake outlet.

At this time, the displacement sensor 82 measures the position of the back pressure plate 81 and sends the measured data to the control device 11 so that the opening area is appropriate. The solenoid valve 84 is controlled so that the area of the opening becomes as follows. The displacement sensor 82 may be any sensor that can measure the amount of displacement in the position of the back pressure plate 81 either by contact or non-contact, and the measurement method is not particularly limited.

In addition to the screw press method, belt press methods, multi-disc methods, centrifugal methods, etc. are generally known as sludge dewatering methods, and the method is not limited to any one of them. However, from the viewpoint of maintainability and automation, the screw press method is preferable. In the case of the screw press method, the water content of the dehydrated cake G can be controlled by at least one of the rotational speed of the screw 73 or the opening area of the dehydrated cake discharge section (position of the back pressure plate 81).

The concentrated trough separation liquid E from the sludge concentration trough 6 and the dehydrator filtrate F from the sludge dehydrator 7 are combined as a dehydrated filtrate H in a dehydrated filtrate trough 74. The flow meter SF3 and the SS concentration meter SD2 measure the flow rate and SS concentration of the dehydrated filtrate H, respectively. At this time, the SS concentration meter SD2 does not have to directly measure the SS concentration, but there is no problem in converting the measured turbidity into the SS concentration using a turbidity meter that has been correlated with the SS concentration in advance. Note that the measured values of the flow meter SF3 and the SS concentration meter SD2 are sent to the control device 11, respectively.

The dehydrated cake G is discharged from the sludge dehydrator 7 via a dehydrated cake discharge section, and the discharged dehydrated cake G is stored in a dehydrated cake storage hopper 10 via a dehydrated cake transfer conveyor 9. The dehydrated cake storage hopper 10 includes a hopper 101 and a weight measuring device 102. The weight measuring device 102 measures the weight of the dehydrated cake G stored in the hopper 101. When this weight reaches a predetermined weight reference value, the series of steps shown in FIG. 1 ends. Further, the dehydrated cake G stored in the hopper 101 is carried out of the site, and is then disposed of as waste or recycled as a material such as compost or cement material.

Here, the sludge A to be treated is typically sludge generated in a sewage water treatment system. In the following, explanation will be given using this sewage sludge as an example. However, the sludge treatment system of FIG. 1 is not limited to this, and can be applied to facilities having a coagulation-mixing process and/or dewatering process in industrial wastewater including sewage, water supply, industrial water facilities, etc. In particular, the coagulation-mixing process can be applied to solid-liquid separation for SS and turbidity reduction in water supply facilities, solid-liquid separation tanks for SS and turbidity reduction in industrial wastewater, pressurized flotation equipment, etc. Furthermore, the flocculating floc measurement device 5 can also be applied to monitoring the sedimentation status of solids such as biological flocs, not limited to sludge, in a solid-liquid separation process at a sedimentation site, etc., even without a coagulation-mixing process.

《Sludge treatment system and sludge treatment method (comparative example) and their problems》
FIG. 5 is a flow diagram showing an example of an operating method in a sludge treatment system that is a comparative example of the present invention. The operation flow shown in FIG. 5 is mainly executed by driving operations by on-site engineers. For example, in FIG. 1, the sludge treatment system serving as a comparative example has a configuration in which the floc measurement device 5, the sludge concentration trough 6, the flow meter SF3 and the SS concentration meter SD2, the control device 11, etc. are not included. In FIG. 5, the engineer first confirms the flow rate and concentration of the sludge A to be treated using the flow meter SF1 and the concentration meter SD1, and sets the flow rate of the sludge A to be treated using the sludge supply pump P1. (Step S501).

Next, based on the flow rate and concentration in step S501 and reflecting past performance, the engineer determines the amount of coagulant B added, the stirring intensity of the stirring device 42 by the drive device M1, and the screw 73 by the drive device M2. The pressure of the back pressure plate 81 is determined manually or by a drive device (step S502). After operating the sludge treatment system in this state for a predetermined period, the engineer visually confirms the formation state of the coagulated flocs C and the SS of the dehydrator filtrate F (steps S503 and S504), and removes the dehydrated cake G. The water content is confirmed visually or by measurement using a moisture meter (step S505).

If any of the confirmation results in steps S503 to S505 are defective, the engineer returns to step S501 and/or step S502 and changes the flow rate of sludge A to be treated or changes the flow rate of flocculant B based on past performance. At least one of changing the amount added, changing the stirring intensity of the stirring device 42, changing the rotational speed of the screw 73, and changing the pressure of the back pressure plate 81 is carried out. On the other hand, if the confirmation results in steps S503 to S505 are good, the engineer measures the hopper weight using the weight measuring device 102, and continues the operation of the sludge treatment system until the hopper weight reaches the weight standard value. (Step S506).

Furthermore, while continuing the operation in step S506, the engineer repeats the confirmation work in steps S503 to S505 as necessary. When the hopper weight reaches the weight standard value in step S506, the engineer or worker cleans the various devices using automatic cleaning devices built into the various devices (step S507), and further cleans the various devices as necessary. Various devices are manually cleaned (step 508).

In this way, the operation flow shown in FIG. 5 is performed based on the personal judgment of a skilled engineer who fully understands the conditions of the facilities and equipment. However, in recent years, due to social factors such as an aging population and a shortage of the working population, there has been a shortage of engineers, making it difficult to pass on skills. Therefore, automation of the sludge treatment system is desired. In this case, it is conceivable to achieve local automation using, for example, the techniques disclosed in Patent Documents 1 to 3.

In the methods of Patent Documents 1 and 2, the moisture content of dehydrated sludge (dehydrated cake G) is measured by a moisture meter, and the sludge dewatering machine is controlled based on the measurement result. However, the measured values by the moisture meter may vary widely, and it is not always possible to control the moisture content below a moisture content reference value (for example, 80%, etc.). That is, a moisture meter is generally suitable for measuring low moisture content, and is often unable to measure high moisture content with high accuracy. In this case, the control that reflects the measurement results of the moisture analyzer (back pressure plate pressure control or screw rotation speed control) is not necessarily appropriate, so the engineer should check the appropriateness of the control (or the measurement results). It may be necessary to confirm the validity of the

Furthermore, in the sludge dewatering machine, it is desirable to control not only the water content of the dehydrated cake G as shown in Patent Documents 1 and 2, but also the SS recovery rate. That is, for example, when attempting to obtain a dehydrated cake G with a low moisture content in a state where the physical strength of the coagulated flocs C is weak and insufficient, control is performed in the direction of increasing the pressure of the back pressure plate 81. However, in this case, a situation may arise in which most of the sludge in the coagulated flocs C flows out from the screen 72 as the dewatered filtrate H.

In the method of Patent Document 3, the agglomerated state of the agglomerated flocs C is photographed with a camera, and the amount of coagulant B added is adjusted based on the photographed data. However, when photographing the coagulated flocs C with a camera, the coagulated flocs C may overlap each other, and sludge may adhere to the measuring part due to the water contained in the coagulated flocs containing polymer or the like. For this reason, accurate evaluation may become difficult and frequent maintenance may be required. That is, the intervention of a technician or the like may be required to some extent.

As described above, even if the technologies disclosed in Patent Documents 1 to 3 are used, a certain amount of personnel is still required in some processes, and there is a risk that the problem of lack of engineers and technology inheritance cannot be sufficiently alleviated. . Moreover, when the method of Non-Patent Document 1 is used, the dehydration properties of the dehydrated cake can be improved. However, although the dewatering performance improves, the amount of sludge attached increases, so for example, in the cleaning process that is performed as necessary after completing one example of treatment, the frequency of cleaning the screen 72 etc. using an automatic cleaning device is reduced. The amount of washing water will increase, and furthermore, there is a possibility that the amount of manual washing work will also increase.

《Sludge treatment method (embodiment)》
2A and 2B are flowcharts showing an example of detailed processing contents of the control device in the sludge treatment system of FIG. 1. The control device 11 executes the flows of FIGS. 2A and 2B by program processing using a computer system, for example. In FIG. 2A, the control device 11 issues an instruction to start operation to the treated sludge supply pump P1, the flocculant supply pump P2, the stirring device 42, and the sludge dehydrator 7 (step S101).

Subsequently, the control device 11 measures the flow rate and concentration of the sludge A to be treated using the flowmeter SF1 and the concentration meter SD1 (step S102). Next, the control device 11 calculates the amount of solids in the sludge A to be treated based on the measured value in step S102, and determines the amount of flocculant B added according to this amount of solids (step S103). Specifically, the control device 11 controls the flocculant supply pump P2 so that the predetermined addition amount is achieved.

The amount of flocculant B added to the amount of solids in the sludge A to be treated is determined by, for example, testing in advance the correspondence between the amount of solids, the amount of flocculant B added, and the size of the flocs C produced in the flocculating mixer 4. It is determined based on the actual performance or past driving results. In the example of FIG. 1, the control device 11 controls the flocculant supply pump P2 while measuring the amount of flocculant B added using the flowmeter SF2. However, if the flow rate adjustment of the flocculant supply pump P2 is highly accurate, Flow meter SF2 is not necessarily required.

The coagulation-mixing device 4 stirs the treated sludge A and the flocculant B using the stirring device 42 to generate floc-formed water D containing coagulated flocs C. The control device 11 measures the size of the agglomerated floc C using the agglomerated floc measuring device 5 (step S104). Here, if the size of the coagulated flocs C is too small, the coagulated flocs C will leak from the screen 72 of the sludge dehydrator 7 during the dewatering process, and/or will similarly leak from the screen 72 due to back pressure on the back pressure plate 81. do. In this case, it becomes difficult to perform desired dehydration treatment in the dehydration step. On the other hand, if the amount of flocculant B added is excessive, it generally becomes difficult to form agglomerated flocs C, and the liquid itself becomes thicker, leading to a significant increase in the cost of the flocculant.

Therefore, the preferred size of coagulated flocs C in sewage sludge is desirably controlled to be 5 to 100 mm, more preferably 10 to 50 mm. However, since the properties of sludge vary depending on each treatment facility and the season, the size of the coagulated flocs C is not necessarily limited to this range, and is preferably corrected based on information on past coagulated flocs C. Here, in FIG. 5, a person visually checks the size of the coagulated flocs C in the coagulating mixing tank 41 on a regular basis, and through this regular monitoring, the amount of coagulant B added and the amount of sludge A to be treated are determined. The amount added was adjusted sequentially.

On the other hand, in the embodiment, continuous monitoring is performed using the agglomerated floc measuring device 5. In the example of FIG. 1, an acoustic measurement method using an acoustic measurement device 51 or the like is used as the aggregated floc measuring device 5, but depending on the case, an imaging method may be used as in the case of Patent Document 3. In the imaging method, a camera installed above the coagulation mixing tank 41 or underwater photographs the coagulated flocs C, and the control device 11 measures the size of the coagulated flocs C by processing the photographed image data. do.

However, when using the imaging method, as described in Fig. 5, there may be cases where coagulated flocs C overlap each other, or sludge may adhere to the measuring part due to the water contained in coagulated flocs C containing polymer. be. Furthermore, in the imaging method, imaging is performed for a limited narrow area, but this area does not necessarily represent all areas. As a result, with the imaging method, accurate measurement may become difficult and frequent maintenance may be required.

On the other hand, when the acoustic measurement method is used, since scanning can be performed in the depth direction, overlapping of the coagulated flocs C does not pose a problem, and sludge does not adhere to the measuring section. Furthermore, in the acoustic measurement method, the size of the aggregated flocs C can be measured in all regions by three-dimensionally controlling the scanning direction. For this reason, an imaging method may be used, but from the viewpoint of measurement accuracy and maintainability, it is preferable to use an acoustic measurement method. Note that, for example, a commercially available fish finder or the like can be used as the aggregated floc measurement device 5 using the acoustic measurement method. Therefore, it can be realized at low cost. The frequency of the sound waves emitted by the acoustic transceiver 52 is desirably 200 kHz or more, preferably 400 kHz or more, considering the size of the coagulated flocs C to be recognized and the water depth of the coagulation mixing tank 41 (for example, about 1 m).

After measuring the size of the agglomerated flocs C in this way (step S104), the control device 11 determines whether the measured size of the agglomerated flocs C satisfies a predetermined reference value (specifically, whether it is within the reference range or not. (step S105). If the size is outside the standard range, the control device 11 controls the amount of flocculant B added via the flocculant supply pump P2 to 1 to 20%, preferably 3 to 10% of the current value, as shown in FIG. 2B. It is increased or decreased by a certain percentage (step S301). Specifically, the control device 11 reduces the amount added when the size is large, and increases the amount added when the size is small.

Thereafter, the control device 11 measures the size of the aggregated flocs C again after about 0.1 to 20 minutes, preferably about 0.5 to 10 minutes (step S302). Here, if the size is still outside the standard range, the control device 11 increases the supply amount of the sludge A to be treated via the sludge supply pump P1 to a rate of 1 to 20%, preferably 3 to 10% of the current value. (step S303). Specifically, the control device 11 increases the supply amount when the size is large, and decreases the supply amount when the size is small. Then, the control device 11 changes the rotation speed of the agitation device 41 via the drive device M1 in accordance with the change in the supply amount of the sludge A to be treated, so that the agitation intensity is set in advance (step S304). .

In this state, the control device 11 evaluates the size of the aggregated flocs C again after about 0.1 to 20 minutes, preferably about 0.5 to 10 minutes (step S305). If the size is still outside the reference range, the control device 11 returns to step S301 and changes the amount of coagulant B added again. Note that if the size of the agglomerated flocs C falls within the reference range after such changes, the control device 11, for example, returns various conditions to the immediately previous conditions and moves to the process of step S102 (step S302, S305). Here, if the amount of added flocculant B is smaller than the initial setting value, or if the amount of sludge A to be treated is larger than the initially set value, the operation may be continued without returning to the previous conditions. In this way, continuous monitoring using the control device 11 makes it possible to generate good coagulated flocs C, contributing to stable operation of the sludge dewatering machine 7.

The floc-produced water D containing the coagulated flocs C thus produced in the coagulation-mixing device 4 is transferred to the sludge dehydrator 7 via the sludge thickening trough 6. At this time, the sludge concentration trough 6 uses the screen 62 to separate moisture and sludge from the floc-generated water D. Then, the sludge concentration trough 6 supplies the concentrated flocs C, which becomes sludge, to the sludge dehydrator 7, and the concentrated trough separated liquid E, which becomes water, flows into the dewatered filtrate trough 74 of the sludge dehydrator 7, and dewaters it. Mix with filtrate H.

The coagulated flocs C supplied to the sludge dehydrator 7 are further drained by a screen 72 while being transported by a screw 73 driven by a drive device M2. When the agglomerated flocs C are transferred to the back pressure plate 81, which serves as a discharge section for the dehydrated cake G, the back pressure plate 81 performs consolidation, and water is further removed. On the other hand, the concentrated trough separation liquid E separated in the sludge concentration trough 6 joins with the dehydrator filtrate F in the dewatered filtrate trough 74, and is normally returned to the water treatment system as the dehydrated filtrate H.

Here, in step S106 of FIG. 2A, the control device 11 measures the flow rate and SS concentration of the dehydrated filtrate H using the flow meter SF3 and the SS concentration meter SD2. Then, the control device 11 uses the measured values of the flow meter SF3 and the SS concentration meter SD2 and the measured values of the flow meter SF1 and the concentration meter SD1 measured in step S102 to determine the SS recovery rate r [%] and the dewatering rate. The cake moisture content u [%] is calculated (steps S107, S108). The SS recovery rate r is calculated by equation (1), and the dehydrated cake moisture content u is calculated by equation (2).
r=[1-(Qo×Co/Qi×Ci)]×100…(1)
u=[(Ki×Qi-Ko×Qo)-(Qi×Ci-Qo×Co)]/(Ki×Qi-Ko×Qo)×100...(2)

In equations (1) and (2), Qi [m ³ /h] is the flow rate of the sludge A to be treated measured by the flowmeter SF1, and Qo [m ³ /h] is the flow rate of the dewatered filtrate H measured by the flowmeter SF3. It is the flow rate. Ci [t/m ³ ] is the concentration of the sludge A to be treated measured by the densitometer SD1, and Co [t/m ³ ] is the SS concentration of the dewatered filtrate H measured by the SS densitometer SD2. Ki indicates the specific gravity set in advance from the Ci and Co of the sludge to be treated A, and Ko indicates the specific gravity of the dewatered filtrate H. However, if Ci is sufficiently low, then there is no problem even if Ki and Ko are set to a specific gravity of 1. . “Qi×Ci” represents the amount of solids contained in the sludge A to be treated, and “Qo×Co” represents the amount of solids contained in the dewatered filtrate H. “Qi×Ci−Qo×Co” represents the amount of solids contained in the dehydrated cake G, and “Ki×Qi−Ko×Qo” represents the sum of the amount of water and the amount of solids contained in the dehydrated cake G.

Subsequently, in step S109, the control device 11 compares the SS recovery rate r calculated in step S107 with a predetermined recovery rate reference value (for example, 90 to 95%, etc.), and determines whether the SS recovery rate r is the recovery rate. If the reference value is not satisfied (for example, less than 90 to 95%), the process moves to step S401 in FIG. 2B, and the operating conditions of the sludge dehydrator 7 are changed. In step S401 of FIG. 2B, the control device 11 determines the clearance dimension (opening area) of the dehydrated cake outlet. Then, the control device 11 sets the clearance dimension (opening area) of the dehydrated cake outlet to the value determined in step S401 via the solenoid valve 84 while referring to the measured value of the displacement sensor 82 (step S402). (Step S403).

Furthermore, the control device 11 changes the rotational speed of the screw 73 via the drive device M2, and then proceeds to step S102 in FIG. 2A (step S404). A situation in which the SS recovery rate r does not meet the recovery rate standard value is a situation where sludge (for example, 10 to 5% or more sludge) does not become a dehydrated cake G and flows out from the screen 72 as a dehydrated filtrate H. Therefore, the control device 11 performs the processes of steps S401 to S404 in order to suppress this outflow. At this time, the position of the back pressure plate 81 is controlled not by the pressure of the back pressure plate 81 as in Patent Documents 1 and 2, but from the viewpoint of suppressing the outflow of sludge with high precision via the displacement sensor 82.

Here, the rotational speed of the screw 73 and the clearance dimension (opening area) of the dehydrated cake outlet are initially set to initial values. Specifically, the control device 11 calculates the amount of solids based on the values of the flowmeter SF1 and the concentration meter SD1, and adjusts the rotational speed of the screw 73 and the clearance of the dehydrated cake outlet that are predetermined in accordance with the amount of solids. Set the dimensions (opening area) as initial values. In this state, if the SS recovery rate r is less than the recovery rate reference value, the control device 11 changes the direction to increase the clearance dimension (opening area) of the dehydrated cake discharge port and decrease the rotation speed of the screw 73. .

Specifically, the clearance dimension (opening area) of the dehydrated cake outlet is changed, for example, by 1 to 50% of the current value, preferably 3 to 30%, and the rotational speed of the screw 73 is changed, for example. The current value is changed to a lower value of 5 to 90%, preferably 10 to 75%. Then, the control device 11 continues operation in this changed state for about 5 to 120 minutes, preferably about 10 to 60 minutes. Thereafter, if the SS recovery rate r improves, the control device 11 may return the rotational speed of the screw 73 and the clearance dimension (opening area) of the dehydrated cake outlet to the previous conditions; Compare it with the set value, and if there is no problem, you may continue the operation without returning to the previous condition.

Subsequently, in step S110 of FIG. 2A, the control device 11 compares the dehydrated cake moisture content u calculated in step S108 with a predetermined moisture content reference value (for example, 70%, etc.). Then, if the dehydrated cake water content u does not satisfy the water content reference value (for example, 70% or more), the control device 11 proceeds to step S401 of FIG. 2B through the process of step S112, which will be described later. Change the operating conditions of machine 7. The method of changing the operating conditions at this time is partially different from that for the SS recovery rate r described above.

In steps S401 to S404 of FIG. 2B, the control device 11 narrows the clearance dimension (opening area) of the dehydrated cake outlet and decreases the rotational speed of the screw 73 in order to reduce the water content u of the dehydrated cake. Control. Specifically, the clearance dimension (opening area) of the dehydrated cake outlet is controlled to narrow, for example, by 1 to 50% of the current value, preferably 3 to 30%, and the rotational speed of the screw 73 is controlled to narrow, for example, by a ratio of 1 to 50%, preferably 3 to 30% of the current value. It is controlled to decrease the value to a value of 5 to 90%, preferably 10 to 75%. The control device 11 continues to operate in the changed state for 1 to 120 minutes, preferably 3 to 60 minutes, and then, if the dehydrated cake moisture content u improves, the clearance dimension (opening area) of the dehydrated cake outlet is ) and the rotational speed of the screw 73 may be returned to the immediately previous conditions, but the dehydrated cake water content u may be compared with the set value and if there is no problem, the operation may be continued without returning to the immediately previous conditions.

On the other hand, if the water content u of the dehydrated cake has not improved, the control device 11 moves from step S404 in FIG. 2B to step S102 in FIG. 2A to step S110, and then returns to step S401 in FIG. 2B. Then, the control device 11 repeats the same process as that described above in steps S401 to S404 of FIG. 2B. Note that in steps S401 to S404 in FIG. 2B, the control device 11 changes both the rotational speed of the screw 73 and the clearance dimension (opening area) of the dehydrated cake outlet, but in some cases, at least one of the may be changed.

The dehydrated cake G dehydrated by the sludge dehydrator 7 is finally stored in the dehydrated cake storage hopper 10. In FIG. 2A, when both the SS recovery rate r and the dehydrated cake water content u satisfy the reference values (steps S109, S110), the control device 11 stores a predetermined amount of dehydrated cake G in the dehydrated cake storage hopper 10. The processing of steps S102 to S110 is repeated until (step S111).

Specifically, the control device 11 measures the weight of the dehydrated cake G stored in the hopper 101 using the weight measuring device 102, and compares the measured weight of the dehydrated cake G with a predetermined weight reference value. compare. Then, when the measured weight of the dehydrated cake G satisfies the weight standard value (when it exceeds the weight standard value), the control device 11 moves to step S201. Furthermore, even if the water content u of the dehydrated cake is not improved in step S112, if a predetermined amount of dehydrated cake G is stored in the dehydrated cake storage hopper 10, the control device 11 proceeds to step S201.

In step S201, the control device 11 issues an instruction to stop the operation of the treated sludge supply pump P1, the flocculant supply pump P2, and the stirring device 42, thereby ending the dewatering process and moving to the automatic cleaning process of step S202. . In step S202, the control device 11 issues a cleaning start command to an automatic cleaning device (not shown) installed in the sludge dehydrator 7 and/or the coagulation-mixing device 4. In response to this, the automatic cleaning device uses a cleaning nozzle to wash the areas where each sludge adheres with water. Thereafter, in step S203, the control device stops the sludge dehydrator 7, and ends the series of processes.

Here, in the sludge treatment system shown in FIG. 1, water repellent treatment using fluorine-based and/or silicone-based or vapor deposition is applied to areas that come into direct contact with sludge. Therefore, the adhesion of sludge is reduced, and the amount of water and time required for cleaning in step S202 are reduced, so that operational costs can be reduced. Furthermore, manual cleaning becomes unnecessary. The parts that come into direct contact with the sludge include the inner surface of the coagulation mixing tank 41, the stirring device 42, the inner and outer surfaces of the screen 62 of the sludge thickening trough 6 and the screen 72 of the sludge dehydrator 7, the screw 73, and the dewatered filtrate trough 74. , and the back pressure plate 81 of the back pressure section clearance adjustment device 8. At least some, preferably all, of these locations are treated to be water repellent.

As described above, automation of the sludge treatment system can be realized by using the sludge treatment system of FIG. 1 and the processing flows of FIGS. 2A and 2B. In particular, in step S108 of FIG. 2A, the control device 11 calculates the dehydrated cake water content u based on the measured values of the flow meter SF1 and the concentration meter SD1, and the measured values of the flow meter SF3 and the SS concentration meter SD2. There is. Therefore, highly accurate dehydrated cake moisture content u can be obtained in real time. In other words, as described in FIG. 5, when the methods of Patent Documents 1 and 2 are used, confirmation work by an engineer or the like may be required, but without such confirmation work, the dehydrated cake contains water. It becomes possible to automatically optimize the rate u. Furthermore, by using an acoustic measurement method as the floc measuring device 5 and by applying water repellent treatment to the parts that come into direct contact with the sludge, the need for manpower for maintenance, cleaning, etc. is eliminated.

Note that the measured values by the flow meters SF1 to SF3 and the concentration meters SD1 and SD2, the measured values by the floc measuring device 5, the measured values by the displacement sensor 82, the control amounts of the drive devices M1 and M2, etc. are recorded as data from the control device 11. Stored sequentially on media. Then, the control device 11 or another information processing device determines further optimized operating conditions based on the various data stored in the data recording medium using an analysis tool including artificial intelligence (AI). . Further, depending on the case, the moisture content of the dehydrated cake G can be measured using image sensing data from the shape at the time of discharge, falling speed, falling position, etc.

《Details of sludge thickening trough》
FIG. 3 is a diagram showing a detailed arrangement example of the sludge thickening trough in FIG. 1, and FIG. 4(a), FIG. 4(b), and FIG. It is a figure which shows an example. As shown in FIG. 3, the sludge thickening trough 6 is installed between the coagulation-mixing device 4 and the sludge dewatering machine 7. The screen 62 is installed at an angle θ of, for example, 20 to 80 degrees, preferably 30 to 70 degrees, with respect to the horizontal plane.

4(a) is a plan view of the sludge thickening trough 6, FIG. 4(b) is a sectional view taken along line XX′ in FIG. 4(a), and FIG. FIG. 3 is a sectional view taken along YY′ in FIG. When the configuration shown in FIG. 4(b) is rotated clockwise and installed, the state shown in FIG. 3 will be obtained. As shown in FIGS. 4(b) and 4(c), the sludge thickening trough 6 includes an upper bottom corresponding to the screen 62 (62a, 62b) and a lower bottom corresponding to the bottom plate 65. The screen 62 (62a, 62b) separates moisture from the coagulated flocs C transferred on the screen, and the bottom plate 65 transfers the concentrated trough separated liquid E separated and discharged by the screen to the sludge concentrated trough separated liquid piping. 61 and mixed with the dewatered filtrate H of the sludge dehydrator 7.

Furthermore, a water stop plate 64a and a water stop plate 64b are provided at the upstream end and downstream end of the sludge concentration trough 6, respectively, as shown in FIGS. 4(a) and 4(b). Further, in the sludge concentration trough 6, side plates 63a and 63b are provided on both sides of the coagulated flocs C with respect to the transfer direction, as shown in FIG. 4(c). Here, the screen 62 includes a plurality of (two in the example of FIGS. 4A and 4B) screen areas 62a and 62b having different widths of moisture discharge ports.

The screen area 62a is provided on the upstream side of the coagulation mixer 4, and the screen area 62b is provided on the downstream side of the sludge dehydrator 7. For example, the width of the screen area 62a on the upstream side is set to 0.5 to 10 mm, and the width of the screen area 62b on the downstream side is set to 0.1 to 5 mm. However, the number of divisions of the screen area is not limited to two, but may be three or more. That is, the screen 62 may be configured such that at least the width of the screen area 62a on the coagulation-mixing device 4 side is larger than the width of the screen area 62b on the sludge dehydrator 7 side.

On the upstream side, since agglomerated flocs C having relatively high strength pass through, even if the mesh width is increased, the agglomerated flocs C are unlikely to leak into the concentrated trough separation liquid piping 61. Therefore, on the upstream side, the dewatering efficiency can be increased by increasing the mesh width of the screen area 62a. On the other hand, on the downstream side, depending on the situation, agglomerated flocs C having relatively low strength may pass through. Therefore, on the downstream side, by reducing the mesh width of the screen area 62b, the dewatering efficiency can be increased to the extent that leakage of the coagulated flocs C to the concentrated trough separation liquid piping 61 can be sufficiently prevented.

The type of screen used in the screen 62 is not particularly limited as long as it has a sludge concentration effect, such as a wedge wire screen, a punched metal screen, a bar screen, and/or a mesh. In addition, the material and surface treatment of the contact parts of the coagulated flocs C, such as the screen 62, side plates 63a, 63b, water stop plates 64a, 64b, etc. that constitute the sludge concentration trough 6, are metal, painted metal, or coated metal. It may be a water-repellent material, a fluorine-based material and/or a silicone-based material, a material subjected to water-repellent treatment by vapor deposition, or a resin. In particular, sludge adhering to the screen 62 causes clogging of the screen 62, so by using members that have been treated with water repellency, clogging can be suppressed, and furthermore, cleaning can be facilitated, and the frequency of cleaning can be reduced. Water volume can be reduced.

By using such a sludge concentration trough 6, the sludge concentration of the coagulated flocs C from the flocculating mixer 4 is concentrated to, for example, 1.5 to 2 times or more, and the concentrated flocs C are transferred to the sludge dehydrator 7. Therefore, it is possible to contribute to reducing the water content of the dehydrated cake G. Here, for example, as shown in Patent Documents 1 and 2, there are known concentrators in which a disk is rotated by external power. In comparison, when the sludge thickening trough 6 of the embodiment is used, no external power is required, so it is possible to save power in the system and, in turn, reduce operating costs.

《Main effects of the embodiment》
As described above, by using the sludge treatment system and sludge treatment method of the embodiment, it is possible to optimize the coagulated flocs C and the operating conditions of the sludge dehydrator 7 through automatic control based on the information obtained through highly accurate monitoring. can be converted into As a result, it becomes possible to alleviate the problem of lack of technical personnel or technology inheritance. Furthermore, manual cleaning work after the dehydration process is no longer necessary, and ideally, a sludge treatment system that does not require manual labor from beginning to end can be realized. This also makes it possible to increase the operating rate of the sludge treatment system.

Further, it becomes possible to reduce operating costs. For example, in the case of FIG. 5, engineers often set the amount of flocculant B to be added to a relatively large amount in order to reliably generate coagulated flocs C. Flocculant B, in particular, causes an increase in cost. When the method of the embodiment is used, excessive addition of flocculant B is eliminated by optimization of operation based on highly accurate monitoring.

Furthermore, it is possible to reduce the amount of sludge carried out. Specifically, by performing various controls while monitoring the moisture content of the dehydrated cake G with high precision, the moisture content of the dehydrated cake G can be maintained at a sufficiently low value. As a result, in the hopper 101, instead of dehydrated cake G with a high moisture content (in other words, a dehydrated cake containing unnecessary moisture), dehydrated cake G with a sufficiently low moisture content is stored and transported. Therefore, the amount of sludge carried out can be reduced.

As above, the invention made by the present inventor has been specifically explained based on the embodiments, but the present invention is not limited to the embodiments described above, and various changes can be made without departing from the gist thereof. For example, the embodiments described above have been described in detail to explain the present invention in an easy-to-understand manner, and the present invention is not necessarily limited to having all the configurations described. Further, it is possible to replace a part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. . Furthermore, it is possible to add, delete, or replace some of the configurations of each embodiment with other configurations.

4 Coagulation mixing device 5 Coagulation floc measuring device 6 Sludge concentration trough 7 Sludge dehydrator 11 Control device 51 Acoustic measuring device 52 Acoustic transceiver 62 Screen 62a, 62b Screen area 65 Bottom plate 73 Screw 101 Hopper 102 Weight measuring device A Sludge to be treated B Coagulant C Coagulated floc E Concentrated trough separated liquid G Dehydrated cake H Dehydrated filtrate SD1, SD2 Density meter SF1 to SF3 Flow meter

Claims (4)

a coagulation-mixing step in which a coagulation-mixing device receives the sludge to be treated generated in the water treatment system, mixes a flocculant into the sludge to be treated, and generates coagulated flocs by stirring at a predetermined stirring intensity;
A dewatering step in which a sludge dehydrator separates and removes water from the flocs to produce a dehydrated cake with a reduced water content, which is then stored in a hopper and discharges a dehydrated filtrate corresponding to the water;
A sludge treatment method comprising:
The dehydration step includes:
A first step in which a predetermined measuring device measures the flow rate and concentration of the sludge to be treated that is supplied to the coagulation-mixing device , and the flow rate and SS concentration of the dewatered filtrate;
The control device calculates the moisture content of the dehydrated cake based on the measured value of the first step, compares the moisture content with a predetermined moisture content reference value, and determines whether the moisture content is the moisture content reference value. a second step of changing the operating conditions of the sludge dewatering machine if the values are not met ;
The control device calculates an SS recovery rate based on the measured value of the first step, compares the SS recovery rate with a predetermined recovery rate reference value, and determines whether the SS recovery rate is the recovery rate reference value. a fifth step of changing the operating conditions of the sludge dehydrator if the conditions are not satisfied;
has
The sludge dehydrator is a screw press type device including a screw and a dehydrated cake outlet through which the dehydrated cake is discharged,
When changing the operating conditions of the sludge dehydrator in the second step or the fifth step, the control device changes at least one of the rotational speed of the screw or the opening area of the dewatered cake outlet. death,
In the second step, when the moisture content is equal to or higher than the moisture content reference value, the opening area of the dehydrated cake outlet is controlled to be narrower, and in the fifth step, the SS recovery rate is reduced. is less than the recovery rate reference value, controlling the opening area of the dehydrated cake outlet in a direction to increase it;
Sludge treatment method. The sludge treatment method according to claim 1,
The aggregation and mixing step includes:
a third step in which an agglomerated floc measuring device measures the size of the agglomerated floc;
The control device compares the size of the coagulated flocs with a predetermined size standard value, and if the size of the coagulated flocs does not meet the size standard value, the control device adjusts the supply amount of the sludge to be treated and the amount of the flocculant. a fourth step of changing at least one of the supply amount and the stirring intensity;
has,
Sludge treatment method. The sludge treatment method according to claim 1 or 2,
The dehydration step further includes a sixth step in which a weight measuring device measures the weight of the dehydrated cake stored in the hopper,
The sludge treatment method further includes the control device comparing the weight of the dehydrated cake measured in the sixth step with a predetermined weight standard value, and determining whether the weight of the dehydrated cake satisfies the weight standard value. a cleaning step of issuing a cleaning start command to an automatic cleaning device installed in the coagulation-mixing device or the sludge dehydrator when
Sludge treatment method. The sludge treatment method according to claim 1 or 2,
In the second step or the fifth step, when controlling the opening area of the dehydrated cake outlet, the control device controls the position of a back pressure plate provided at the dehydrated cake outlet using a displacement sensor. controlling the position of the back pressure plate while detecting it using
Sludge treatment method.

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