JP5974385B2 - Organic sludge anaerobic solubilization digestion treatment system and organic sludge anaerobic solubilization digestion treatment method - Google Patents

Description

  The present invention relates to an anaerobic solubilization digestion processing system for organic sludge and an anaerobic solubilization digestion processing method for organic sludge.

  As a method for treating organic sludge such as sewage sludge and industrial wastewater, anaerobic digestion treatment in which anaerobic microorganisms such as methane bacteria are digested is exemplified.

Moreover, according to the following Patent Document 1, in order to increase the amount of methane gas to be recovered and to reduce the volume of sludge by digestion sludge thermal reforming, the digested sludge subjected to anaerobic digestion is heat-solubilized and solubilized sludge. A highly efficient anaerobic solubilization digestion method is disclosed that circulates the gas to the digestion tank.
In addition, the anaerobic solubilization digestion processing method of the following patent document 1 is solubilized by mixing digestion sludge with the dewatered cake pressure-fed to the heat-solubilized retarder, and adjusting the moisture content (solid content concentration) of the dehydrated cake. By adjusting the amount of heat, it is possible to maintain the organic sludge in the digestion tank at the temperature required for anaerobic digestion without using a heat exchanger.

JP 2010-179216 A

  However, in the conventional anaerobic solubilization digestion treatment system, in order to adjust the heat of solubilization to the heating heat of the digestion tank, the dewatered cake that is solubilized by controlling and adjusting the flow rate of the dehydrated cake and the flow rate of the digested sludge Since it was necessary to adjust the water content of the flow rate, the flow rate management was complicated. Therefore, an anaerobic solubilized digestion treatment system that can easily control the amount of heat or moisture content of the dehydrated cake has been desired.

  Moreover, in the conventional anaerobic solubilization digestion processing system, the piping resistance of the dewatering cake piping which pumps a dewatering cake to a solubilization tank was high. Moreover, for example, the inside of the solubilization tank was set to a high pressure, such as 0.5 to 0.7 MPa. Then, the dehydrated cake was pumped to a solubilization tank by pumping the dehydrated cake at a very high pressure such as 1.6 to 3.2 Mp with a dehydrated cake pump. For this reason, there has been a problem that the dewatering cake pressure feed pump is enlarged and consumes excessive power.

  Moreover, in the conventional anaerobic solubilization digestion processing system, digested sludge is thrown into the dewatered cake piping in order to adjust the moisture content of the dehydrated cake put into the solubilization tank. For this reason, a pressure pump and piping for supplying digested sludge to the high-pressure dehydrated cake piping are required, and the number of incidental facilities has increased.

  Therefore, the present invention is an invention created in view of the above-described problems, and provides an anaerobic solubilization digestion processing system and an anaerobic solubilization digestion processing method that replace the conventional anaerobic solubilization digestion processing system. Is an issue.

In order to solve the above problems, an anaerobic solubilization digestion processing system according to the present invention includes a digestion tank in which anaerobic digestion treatment of organic sludge is performed, and a circulation line for circulating a part of the digested sludge to the digestion tank. And the first sludge dewatered to be separated into a solubilized dehydrated cake and a separation liquid to be supplied to the solubilization tank by dehydrating the digested sludge flowing on the circulation line. a processing unit, wherein is a the circulation line is located downstream of said first sludge dehydration treatment apparatus, the dehydrated cake pumping device for pumping the dehydrated cake the solubilizer to the solubilizing tank, dehydrating the solubilizer It said solubilizing tank for solubilizing the cake was dehydrated the remainder of the digested sludge, anaerobic solubilization extinguishing includes a second sludge dehydration treatment apparatus for separating the dehydrated cake and separated liquor, and A processing system, said first sludge dehydration treatment apparatus, the by increasing or decreasing the flow rate of the separated liquid discharged from the circulation line, solubilizing quantity of heat required by the solubilizing tank is heated in the digestion tank The water content of the solubilized dehydrated cake is adjusted so that the amount of heat required for the solubilization is obtained.

According to the present invention, the water content of the solubilized dehydrated cake can be adjusted by controlling and adjusting the flow rate of the separation liquid discharged from the circulation line. Therefore, by increasing or decreasing the water content of the solubilized dehydrated cake, the amount of heat of the solubilized sludge can be increased or decreased to make the amount of heat of the solubilized sludge circulating to the digestion tank appropriate.
As described above, according to the present invention, since the flow rate management is only the flow rate of the separation liquid by the dehydration processing device, it is possible to simplify the adjustment management of the amount of heat or the moisture content of the dehydrated cake for solubilization as compared with the prior art. it can.

Further, according to the present invention, the piping and pumping device for the merging line for joining the digested sludge to the dehydrated cake, which has been conventionally required, become unnecessary, and the number of incidental facilities can be reduced.
Furthermore, according to the anaerobic solubilization digestion system of the present invention, dehydrated cake solubilization pumped by the dewatered cake pumping device has a higher moisture content than the conventional dehydrated cake, piping resistance is lowered. Therefore, it is possible to reduce the size of the dewatered cake pumping device and reduce the power consumed.

Further, anaerobic solubilization digestion method according to the present invention, the anaerobic digestion process to produce a digested sludge and organic sludge anaerobic digestion process to the generated by the anaerobic digestion treatment step the digestion A dehydrating process for supplying a part of sludge to the circulation line, and dewatering the digested sludge flowing into the circulation line to separate the dewatered cake for solubilization and the separated liquid to be supplied to the solubilization tank . The first sludge dewatering step, the solubilizing step for solubilizing the solubilized dewatering cake, and the remainder of the digested sludge generated by the anaerobic digestion step are dewatered to separate from the dewatered cake a second sludge dewatering process step of separating into a liquid, a anaerobic solubilization digestion method comprising, in the first sludge dewatering process, increasing the flow rate of the separated liquid discharged from the circulation line By, as solubilizing quantity of heat required by the solubilizing tank is heat required to warm the digestion tank, and adjusting the water content of dehydrated cake the solubilizer.

According to the above-mentioned anaerobic solubilization digestion method, the calorific value of the solubilized sludge circulating in the digestion tank can be adjusted by increasing or decreasing the flow rate of the separation liquid solubilized in the dehydration process. On the other hand, in the water content adjustment of the dehydrated cake solubilization, he is not necessary to adjust the flow rate of the digested sludge to flow on the line of the dehydrated cake solubilization. As described above, according to the present invention, it is possible to simplify the adjustment management of the amount of heat or the moisture content of the solubilized dehydrated cake as compared with the prior art.

In the anaerobic digestion treatment, the temperature of the organic sludge is maintained at 30 ° C. to 60 ° C., and more preferably 35 ° C. to 42 ° C., and the temperature of the solubilized dehydrated cake is 120 ° C. Heat treatment is performed with steam at a temperature of from 160 ° C to 230 ° C, more preferably from 160 ° C to 180 ° C. Furthermore, the solid content of the dewatering cake for solubilization required for the solubilization treatment is desirably 40% to 70%, more preferably 50% to 60%, based on the solid content of the organic sludge. .

ADVANTAGE OF THE INVENTION According to this invention, simplification of adjustment management of the heat content or the moisture content of the dewatering cake for solubilization , and reduction of the number of incidental facilities can be achieved.

It is a block diagram of the anaerobic solubilization digestion processing system which concerns on embodiment. It is sectional drawing which shows the cross section which cut the screw type decanter which concerns on embodiment along the rotating shaft line of the rotating bowl. It is a schematic diagram which shows the usage method of a screw type decanter.

(Anaerobic solubilized digestion treatment system 1)
Below, the anaerobic solubilization digestion processing system 1 which concerns on embodiment is demonstrated, referring drawings.
The anaerobic solubilization digestion treatment system 1 is an anaerobic digestion treatment of organic sludge A generated in water treatment facilities such as a sewage treatment plant or industrial wastewater treatment equipment, and reduces sludge volume and recovers methane gas. It is an object. In addition, the organic sludge A sent to the anaerobic solubilization digestion processing system 1 from water treatment facilities, such as a sewage treatment plant or an industrial wastewater treatment facility, is concentrated by gravity or a mechanical concentration device.
In addition, the anaerobic solubilization digestion system 1 solubilizes the digested sludge B that has been anaerobically digested and again performs anaerobic digestion to reduce the volume by increasing methane gas and sludge reforming. ing.

  As shown in FIG. 1, the anaerobic solubilization digestion processing system 1 includes a digestion tank 2 in which anaerobic digestion of organic sludge A is performed, a digested sludge storage tank 3 that stores digested sludge B, and a digested sludge B. The screw type decanter 4 to be dehydrated, the dewatering cake pressure pump 4 a for pumping the dehydrated cake C from the screw type decanter 4 to the solubilization tank 5, the solubilization tank 5 for solubilizing the dewatering cake C, and the solubilization tank 5 Steam boiler 6 for supplying heat source, sludge dewatering treatment device 7 for reducing and dewatering the digested sludge B for final disposal to landfill or composting after being dried, incinerated or discharged outside the system, and each device Piping 9a-9f which connects between and supplies sludge is provided.

(Digestion tank 2)
The digestion tank 2 is a tank in which anaerobic digestion by anaerobic microorganisms is performed, and the organic content of the input organic sludge A is decomposed in about 15 days to generate digestion gas mainly composed of methane gas. The solid content is reduced to become digested sludge B.
Moreover, in order to promote anaerobic digestion of anaerobic microorganisms, organic sludge is managed by controlling the temperature Ta [° C.] in the digestion tank 2 to 30 ° C. to 60 ° C., preferably 35 ° C. to 42 ° C. A can be processed in a short period of time.

Furthermore, the digestion tank 2 is provided with a digestion gas pipe 2a for collecting digestion gas generated by the anaerobic digestion process. And by a desulfurizer (not shown), hydrogen sulfide is desulfurized from the digestion gas collect | recovered by the digestion gas piping 2a, and the digestion gas is stored in the gas holder.
In addition, the pipe 9a for supplying the organic sludge A to the digestion tank 2 is provided with a flow meter, a thermometer, and a concentration meter (not shown), and the flow rate Qa [m of the organic sludge A charged into the digestion tank 2 is provided. ³ / day], temperature Ta [° C.], and solid content concentration Ca [%] can be monitored and recorded.

(Digested sludge storage tank 3)
The digested sludge storage tank 3 temporarily stores the digested sludge B. In addition, a digested sludge pump 8 (8a, 8b) is provided in each of a pipe 9c connected from the digested sludge storage tank 3 to the screw type decanter 4 and a pipe 9f connected from the digested sludge storage tank 3 to the sludge dewatering apparatus 7. Is provided. Then, by controlling the rotation speed of the digested sludge pump 8 (8a, 8b) with an inverter, the flow rate Qb [m ³ / day] of the digested sludge B supplied to the screw type decanter 4 and the sludge dewatering treatment device 7 are supplied. The flow rate of digested sludge can be adjusted.
Furthermore, in the present embodiment, the flow rate Qb [m ³ / day] of the digested sludge B supplied from the digested sludge pump 8a to the screw type decanter 4 is substantially constant, and the flow rate is managed.

(Screw type decanter 4)
The screw type decanter 4 separates the digested sludge B into a dehydrated cake C and a separation liquid E by centrifuging. The screw type decanter 4 can adjust the water content of the dewatered cake C by increasing / decreasing the flow rate Qe [m ³ / day] of the separation liquid E, and can make the solid content concentration Cc [%] desired. Is. In addition, this screw type decanter 4 is a structure corresponded to the "sludge dewatering processing apparatus" described in a claim.

  As shown in FIG. 2, the screw type decanter 4 has a driving device 22 and a rotation in which a dehydrated cake discharge port 14 is formed on one end side connected to the driving device 22 and a separation liquid port 13 is formed on the other end side. A bowl 11, a screw conveyor 12 that rotates coaxially with the rotation axis of the rotating bowl 11, a separation liquid chamber 15 into which a separation liquid E overflowing from the separation liquid port 13 flows, and a separation liquid disposed in the separation liquid chamber 15. A centripetal impeller 16 that discharges E, a control valve 26 provided in the separation liquid pipe 21 of the centripetal impeller 16, and an operation panel 27 that can control the rotation speed of the drive device 22 are mainly provided.

The rotating bowl 11 has a truncated conical portion 11a having an inclined surface with a diameter reduced toward one end side, and a large-diameter end portion 11b having the same diameter as the other end of the truncated conical portion 11a.
The screw conveyor 12 includes a cylindrical shaft portion 12 a and blades 12 b that are formed on the outer peripheral surface of the shaft portion 12 a and move the solid content to the dewatered cake discharge port 14.
Further, the shaft portion 12a of the screw conveyor 12 is formed with an opening that is formed in the radial direction so as to communicate the inside and the outside of the shaft portion 12a.
And the supply pipe 17 connected to the pipe 9c for supplying the digested sludge B is provided inside the shaft portion 12a, and the digested sludge B flowing from one end of the supply pipe 17 is inserted. The pump is press-fitted and flows into the rotary bowl 11 from the opening of the shaft portion 12a.
The densitometer 19 measures the solid content concentration Cb [%] of the digested sludge B and transmits it to the operation panel for the concentration meter (not shown). %] Can be monitored and recorded.

The centripetal impeller 16 is configured to discharge the separation liquid E in the rotating bowl 11, and is provided so that the outer peripheral portion is immersed in the separation liquid E.
In addition, a flowmeter 25 is provided in the separation liquid pipe 21 connected to the discharge port 16a of the centripetal impeller 16 and through which the separation liquid E flows, and the flow rate Qe [m ³ / day] of the separation liquid E is measured. ing. The measured value by the flow meter 25 is transmitted to the operation panel 27 so that the flow rate Qe [m ³ / day] of the separation liquid E can be monitored and recorded.

The separation liquid pipe 21 is provided with a control valve 26 and a pressure gauge 24. The control valve 26 is for adjusting the Qe [m ³ / day] of the separation liquid E flowing through the separation liquid pipe 21, and the opening / closing amount of the control valve 26 can be adjusted by operating the operation panel 27. It is like that.
As shown in FIG. 3, in this embodiment, the opening / closing amount of the control valve 26 is such that the liquid level of the separation liquid E exceeds the inclined surface of the truncated cone portion 11a in the rotating bowl 11, and the separation liquid There is a case where the operation panel 27 is operated so that an overflow state in which E flows into the dewatered cake discharge port 14 is obtained.

  As described above, according to the screw type decanter 4 configured as described above, the digested sludge B introduced into the rotating bowl 11 is centrifuged and separated into the concentrated dehydrated cake C and the clarified separation liquid E.

Further, when the operation panel 27 is operated so as to reduce the opening degree of the control valve 26, the flow rate Qe [m ³ / day] of the separation liquid E discharged from the separation liquid pipe 21 decreases, so that the dehydrated cake is discharged. The flow rate of the separation liquid E discharged from the outlet 14 increases, and the solid content concentration Cc [%] of the dewatered cake C decreases.
On the other hand, when the operation panel 27 is operated to open the opening of the control valve 26, the flow rate Qe [m ³ / day] of the separation liquid E discharged from the separation liquid pipe 21 increases. The flow rate of the separation liquid E discharged from the dewatered cake discharge port 14 also decreases, and the solid content concentration Cc [%] of the dewatered cake C increases. As described above, the solid content concentration Cc [%] of the dewatered cake C can be adjusted by adjusting the flow rate Qe [m ³ / day] of the separation liquid E discharged from the separation liquid pipe 21.

Moreover, the dewatering cake C discharged | emitted from the dewatering cake discharge port 14 is pumped to the solubilization tank 5 via the piping 9d by the dewatering cake pressure pump 4a, as shown in FIG.
The pipe 9d is provided with a flow meter (not shown), and the flow rate Qc [m ³ / day] of the dewatered cake C to be pumped is measured.
Further, a feeder unit (not shown) that can sample and measure the temperature Tc [° C.] of the dehydrated cake C is provided at the inlet of the dehydrated cake pump 4a into which the dehydrated cake C is fed.

(Solubilization tank 5)
The solubilization tank 5 is a device for solubilizing the dehydrated cake C that has been charged, and a steam flow rate adjusting valve capable of adjusting the amount of steam supplied to the steam supply pipe 5a, and although not shown, the solubilization tank 5 A liquid level adjusting valve and a pressure adjusting valve for adjusting the liquid level and pressure in the inside, a temperature sensor, a pressure sensor, and a liquid level sensor are provided.
In addition, the steam flow regulating valve, the liquid level regulating valve, and the pressure regulating valve are each controlled so that the temperature Tk [° C.] and the pressure in the reactor of the solubilization tank 5 become a predetermined temperature and a predetermined pressure. A solubilization tank control unit that does not perform is provided in a solubilization tank control panel (not shown).
The predetermined temperature is 120 ° C. to 230 ° C., preferably 160 ° C. to 180 ° C., and the predetermined pressure is 0.5 MPa to 1.0 MPa, preferably 0.5 MPa to 0.7 MPa. .

(Steam boiler 6)
The steam boiler 6 generates high-temperature steam to be supplied to the solubilization tank 5 using methane gas generated in the digestion tank 2 as a fuel source. Further, the steam boiler 6 supplies steam to the solubilization tank 5 through a steam supply pipe 5a.

(Sludge dewatering equipment 7)
The sludge dewatering device 7 is a device for dewatering the digested sludge B. And by digesting the digested sludge B with the sludge dewatering processing apparatus 7, it isolate | separates into a dewatering separation liquid and a dewatering cake, and can reduce a dewatering cake.
Then, the recovered dehydrated cake is dried by a drying device and incinerated, or is taken out of the anaerobic solubilization digestion processing system 1 to be landfilled or composted. On the other hand, the dehydrated separation liquid is returned to the sand settling basin or the first settling basin of the water treatment system that performs the activated sludge treatment.

  Piping 9a-9f is a pipe | tube for sending out organic sludge A, digested sludge, etc. arrange | positioned between each apparatus. Note that the pipes 9b to 9e correspond to the “circulation line” described in the claims.

(Operation method of anaerobic solubilized digestion treatment system 1)
Below, the operating method of the anaerobic solubilization digestion processing system 1 which concerns on embodiment is demonstrated. In the anaerobic solubilization digestion processing system, the water content of the dehydrated cake C, that is, the solid content of the dehydrated cake C is adjusted so that the heat of solubilization of the dehydrated cake C and the heat of heating the digestion tank 2 are equal. It is necessary to adjust the concentration Cc [%] to a value calculated by the following equation (1).

“Y” shown in the formula (1) indicates a solubilization rate, and the dehydrated cake C solubilized in the solubilization tank 5 with respect to the solid content of the organic sludge A charged into the digestion tank 2. The ratio of the solid content amount (see formula (8) described later). The solubilization rate Y [%] is set in the range of 40% to 70%, preferably in the range of 50 to 60%.
In addition, “Ca” shown in the formula (1) indicates the solid content concentration [%] of the organic sludge A, “Tk” indicates the temperature [° C.] of the solubilization tank 5, and “Ts” The temperature of the digestion tank 2 [° C.] is indicated, “Tc” indicates the temperature [° C.] of the dehydrated cake C, and “Ta” indicates the temperature [° C.] of the organic sludge A.

Then, the flow rate Qe [m ³ / day] of the separation liquid E in the screw type decanter 4 is set so that the dehydrated cake C to be solubilized has the solid content concentration Cc [%] calculated by the equation (1). , And adjust so as to satisfy the following formula (2). Equation (2-1) is a modification of Equation (2).

In addition, “R” shown in the formula (2) is a formula showing a recovery rate [%] indicating a rate at which the solid content is recovered by the screw type decanter 4 and is a value obtained in advance by an experiment or the like.
In addition, in a dehydration processing machine such as a screw type decanter 4, the amount of processing is determined by the model. Therefore, the flow rate Qb [m ³ / day] of the digested sludge B, which is the amount processed by the screw type decanter 4 of the embodiment, is substituted into “Qb” in the formula (2).
“Cb” shown in Expression (2) is the solid content concentration Cb [%] of the digested sludge B measured by the densitometer 19 of the screw type decanter 4. The value calculated from the equation (1) is substituted into “Cc” shown in the equation (2).

As described above, the solid content concentration Cc [%] of the dehydrated cake is increased or decreased by increasing or decreasing the flow rate Qe [m ³ / day] of the separation liquid E discharged from the screw type decanter 4 so as to be the flow rate obtained by the equation (2). ] Can be set to a value calculated by the equation (1), and the temperature Ts [° C.] in the digestion tank 2 can be maintained at a set temperature necessary for the anaerobic digestion process.

Next, a method for deriving the equations (1) and (2) will be described.
First, a method for deriving Equation (2) will be described. Equation (2) can be derived from Equation (3) to Equation (5) below.
Formula (3) is a formula showing the balance of the flow rate of the sludge flowing into and out of the screw type decanter 4.
Formula (4) is a formula which shows the balance of the amount of solid content flowing into and out of the screw type decanter 4.
The following formula (5) is a formula showing a recovery rate R [%] indicating a rate at which the solid content is recovered by the screw type decanter 4.

In addition, “Qc” shown in Formula (3) indicates the flow rate [m ³ / day] of the dehydrated cake C.

  “Cb” shown in Expression (4) indicates the solid content concentration [%] of the digested sludge B, and a value measured by the densitometer 19 (see FIG. 2) of the screw type decanter 4 is substituted. “Ce” shown in Formula (4) indicates the solid content concentration [%] of the separation liquid E.

  Next, a method for deriving Equation (1) will be described. When the heat balance when the amount of heat necessary for heating the organic sludge A charged into the digestion tank 2 is equal to the amount of heat generated by heating the solubilization tank 5 is expressed by the following equation (6): It becomes.

“F” shown on the left side of the equation (6) is the amount of heat dissipated in the digestion tank 2 and the pipes 9b to 9e, and assuming that 30% of the amount of input sludge heat in the digestion tank is as follows: It becomes like (7).
Moreover, the formula which shows the solubilization rate Y becomes following formula (8). Then, formula (1) can be derived by rearranging formula (6), formula (7), and formula (8). However, the amount of heat dissipated 30% varies from place to place depending on the temperature of the treatment plant, the heat insulation condition, the season, and the like.

  The explanation of the equations (1) to (8) is finished.

  As described above, according to the anaerobic solubilization digestion processing system 1 of the embodiment, when the anaerobic solubilization digestion processing system 1 is operated, the flow rate to be managed is only one of the flow rates Qe of the separation liquid E. Compared with the prior art that manages and adjusts the two flow rates of sludge and dehydrated cake, the management of the amount of heat or the moisture content of dehydrated cake C is simplified.

  Moreover, the anaerobic solubilization digestion processing system 1 of the embodiment has one line for circulating the digested sludge B to the solubilization tank 5. Therefore, according to the anaerobic solubilization digestion processing system 1 of the embodiment, a pipe and a pump for a merging line that join the digested sludge to the dewatered cake required in the conventional anaerobic solubilization digestion processing system. Is not necessary, and the number of incidental facilities can be reduced.

Moreover, according to the anaerobic solubilization digestion processing system 1 of the embodiment,
Since the dewatering cake C pumped by the dewatering cake pumping pump 4a has a higher moisture content than the conventional dewatering cake, the piping resistance of the piping 9d is low. Therefore, it is possible to reduce the size of the dehydrated cake pressure feed pump 4a and reduce the power consumed.

(Operation example)
Next, an example is shown in which the anaerobic solubilization digestion processing system 1 of the embodiment is operated under conditions where the temperature Ta [° C.] of the organic sludge A is Ta = 15 ° C., 20 ° C., and 25 ° C., respectively.
In the anaerobic solubilization digestion processing system 1, the temperature Ta [° C.] of the organic sludge A is easily changed by being affected by the temperature environment. Therefore, Ta = 15 ° C. assumes the winter season, Ta = 20 ° C. assumes the spring and autumn seasons, and Ta = 25 ° C. assumes the summer season.

Further, regarding conditions other than the temperature Ta [° C.] of the organic sludge A, the solubilization rate Y is 50%, and the organic sludge A has a flow rate Qa of 100 m ³ / day and a solid content concentration Ca of 3.5%. To do. The temperature Ts in the digestion tank 2 is 35 ° C., and the digested sludge B has a solid content concentration Cb of 3.0%. The recovery rate R of the screw type decanter 4 is 95%, the temperature Tc of the dewatered cake C is 20 ° C., and the temperature Tk [° C.] in the solubilization tank 5 is 170 ° C.

First, in order to adjust the moisture content of the dewatered cake C under the above conditions, the flow rate Qe [m ³ / day] of the separation liquid E of the screw type decanter is calculated.
When R = 95% and Cb = 3% given from the above conditions are substituted into the above equation (2-1), the following equation (9) is obtained.

  Further, when Y = 50%, Ca = 3.5%, Tk = 170 ° C., Tc = 20 ° C., and Ts = 35 ° C. given from the above conditions are substituted into the equation (1), the following equation (10) is obtained. .

Next, each of 15 ° C., 20 ° C., and 25 ° C. is substituted as the temperature Ta of the organic sludge A in the formula (10).
When Ta = 15 ° C., Cc = 9.8%. Further, when Cc = 9.8% is substituted into the equation (9), Qe / Qb = 0.709 is obtained.
When Ta = 20 ° C., Cc = 13.0%. Further, when Cc = 13.0% is substituted into Expression (9), Qe / Qb = 0.811 is obtained.
When Ta = 25 ° C., Cc = 19.5%. Further, when Cc = 19.5% is substituted into equation (9), Qe / Qb = 0.854.

Here, Qe / Qb indicates the ratio of the flow rate of the separation liquid E discharged from the screw type decanter 4 to the flow rate of the digested sludge B introduced into the screw type decanter 4.
Therefore, for example, when the screw type decanter 4 that processes a flow rate of 15 m ³ / hr is used, when Ta = 15 ° C., the flow rate of the separation liquid E is Qe = 0.709 × 15 from Equation (10). = 10.6 m ³ / hr.
Further, when Ta = 20 ° C., the flow rate of the separation liquid E is Qe = 0.81 × 15 = 11.7 m ³ / hr from the equation (10).
Further, when Ta = 25 ° C., the flow rate of the separation liquid E is Qe = 0.854 × 15 = 12.8 m ³ / hr from the equation (10).
Then, by adjusting the flow rate of the separation liquid E in the screw type decanter 4 so as to be the value calculated by the above calculation, the solubilization heat amount of the dehydrated cake C and the heat amount for heating the digestion tank 2 are equal. Can be adjusted.

  As mentioned above, although the anaerobic solubilization digestion processing system concerning this embodiment was explained, the present invention is not limited to the example explained to the embodiment, and the range which a person skilled in the art can change the design suitably is also included. is there.

DESCRIPTION OF SYMBOLS 1 Anaerobic solubilization digestion processing system 2 Digestion tank 3 Digested sludge storage tank 4 Screw type decanter 4a Dehydrated cake pressure feed pump 5 Solubilization tank 6 Steam boiler 7 Sludge dewatering processing equipment 8 (8a, 8b) Digested sludge pump 9a-9f Piping

Claims (6)

A digestion tank for anaerobic digestion of organic sludge;
A circulation line for circulating a part of the digested sludge to the digestion tank;
A first sludge dewatering apparatus that is installed on the circulation line and dehydrates the digested sludge flowing through the circulation line to separate it into a dewatering cake for solubilization and a separation liquid to be supplied to a solubilization tank. When,
Placed even on the circulation line downstream of said first sludge dehydration treatment apparatus, the dehydrated cake pumping device for pumping the dehydrated cake the solubilizer to the solubilizing tank,
The solubilization tank for solubilizing the dewatering cake for solubilization;
A second sludge dewatering device for dewatering the remainder of the digested sludge and separating it into a dewatered cake and a separated liquid;
An anaerobic solubilized digestion treatment system comprising:
The first sludge dewatering device increases or decreases the flow rate of the separation liquid discharged from the circulation line, so that the solubilization heat amount necessary for the solubilization tank becomes the heat amount necessary for heating the digestion tank. Thus, the anaerobic solubilization digestion processing system characterized by adjusting the moisture content of the dewatering cake for solubilization. In the anaerobic digestion treatment by the digestion tank, the temperature of the organic sludge is maintained at 30 ° C to 60 ° C,
2. The anaerobic solubilization digestion system according to claim 1, wherein the solubilization treatment by the solubilization tank is heat-treated with steam having a temperature of the solubilized dehydrated cake of 120 ° C. to 230 ° C. 3. The solid content of the dewatering cake for solubilization required for the solubilization treatment is 40% to 70% with respect to the solid content of the organic sludge. The anaerobic solubilized digestion treatment system described. And anaerobic digestion process to produce a digested sludge and organic sludge anaerobic digestion process to,
A circulation step for allowing a portion of the digested sludge produced by the anaerobic digestion treatment step to flow into a circulation line;
A first sludge dewatering treatment step of separating the digested sludge flowing into the circulation line into a dewatering cake for solubilization and a separation liquid to be supplied to the solubilization tank ;
A solubilization step for solubilizing the dehydrated cake the solubilizer,
A second sludge dewatering treatment step of dehydrating the remainder of the digested sludge produced by the anaerobic digestion treatment step and separating it into a dehydrated cake and a separation liquid;
An anaerobic solubilized digestion method comprising:
In the first sludge dewatering treatment step, the flow rate of the separation liquid discharged from the circulation line is increased or decreased so that the solubilization heat amount necessary for the solubilization tank becomes the heat amount necessary for heating the digestion tank. And adjusting the water content of the solubilized dehydrated cake. In the anaerobic digestion process, the temperature of the organic sludge is maintained at 30 ° C to 60 ° C,
The anaerobic solubilization digestion method according to claim 4, wherein the solubilization treatment by the solubilization step is performed by heating the dehydrated cake for solubilization with steam at 120 ° C. to 230 ° C. 5. The solid content of the dewatering cake for solubilization required for the solubilization treatment is 40% to 70% with respect to the solid content of the organic sludge to be subjected to the anaerobic digestion treatment. The anaerobic solubilized digestion method according to claim 4 or 5.

Images