CH663203A5 - Plant for the conditioning and sanitation of sewage sludge - Google Patents

Abstract

The plant has an apparatus (13) having three chambers (19, 21, 23). Fresh sewage sludge from the sewage treatment plant (15) is introduced into the chamber (23) and circulated through the chambers (23, 19). Warm sewage sludge from the reactor (11) is introduced into the chamber (21) and circulated. The introduction is carried out via tangential inlets (25, 27, 29), in order to generate rotary movements in an opposite direction within the chambers (23 and 21). The cylindrical object (19) in the chamber (21) prevents plug formation in the centre of the chamber (21) during this, the configuration of the object (19) as a chamber permitting a circulation through this chamber, which considerably accelerates the thermal transfer from the warm sewage sludge to the fresh sludge. … <IMAGE> …

Description

The invention relates to a system for conditioning and sanitizing sewage sludge, with a reactor for heat treatment, in particular for biological heat treatment, a digester for receiving the heat-treated sewage sludge, and a device with at least three practically concentric chambers for fresh sewage sludge before it is introduced into the reactor preheat with hot sewage sludge from the reactor and / or warm sewage sludge from the digester and cool and degas the sewage sludge discharged from the reactor before being forwarded to the digester, and pumps to circulate the sewage sludge contained in the chambers.

In practice, a treatment process for sewage sludge has proven itself, in which the sewage sludge is first hygienized and hydrolyzed by heating to a temperature of> 60 ° C for about 24 hours, after which the sewage sludge pretreated in this way is cooled and in one or more stages in digested sludge is converted. The biological heating of the sewage sludge is particularly advantageous in terms of energy. For example, the European patent 0 053 777 provides that for biological heating to about 70 ° C, oxygen in air or oxygen-containing gas is introduced into the waste materials in a ventilation container, an elevated temperature then being maintained for so long that Enterobacteria and worm eggs are killed. However, not only hygienization but also hydrolysis of the sewage sludge is achieved. This has the advantage that the subsequent digestion is accelerated. The European patent cited provides that after exiting the aeration tank, heat is extracted from the conditioned sewage sludge by means of a heat exchanger and transferred to the fresh sewage sludge.

The unpublished European patent application 0 179 234 also provides for such heating of the sewage sludge, but the fresh sewage sludge is preheated with digested sludge even before this process step. A device with three concentric chambers is provided for heating the fresh sewage sludge, the inner chamber for receiving the fresh sewage sludge from the sewage treatment plant, the middle chamber for alternately receiving the warm sewage sludge from the digestion chamber and the hot sewage sludge from the reactor, while the the outermost chamber is charged with cooling water in order to further cool the digested sludge from the digested area. Circulation pumps are provided to circulate the contents of the inner and middle chambers.

Practice has shown that the systems described require a relatively large amount of time for heat exchange. It is therefore an object of the present invention to improve a system of the type mentioned at the outset in such a way that the heat exchange is accelerated.

According to the invention, this is achieved in that the inlets into the outer and the middle chamber of the device are arranged tangentially in order to bring about a rotary movement of the chamber contents through the inflowing sewage sludge, and that the outer chamber at one end via one of the pumps and at the other end is connected to the central chamber via a line to form a circuit. With this arrangement, the outer and middle concentric chamber have a hollow cylindrical shape. This favors a rotary movement of the chamber contents. Sewage sludge has flow properties that differ significantly from the flow properties of water. In the case of a cylindrical chamber, there is therefore a risk that the content in the vicinity of the center will not participate in the rotary movement, solidify and form a practically stationary plug. This, however, hinders the heat exchange and there is also the risk of malfunctions due to the formation of plugs. In contrast, the formation of a plug is avoided by arranging a cylindrical object in a chamber. Since this cylindrical object also forms a central chamber in the chamber, through which sewage sludge from the outer chamber is circulated, a particularly rapid heat exchange takes place.

According to one embodiment, the sum of the volumes of the central and outer chambers is equal to the volume of the middle chamber. This enables the same volume of sewage sludge to pass through the device per unit of time. The device can therefore also have the same dimensions as the devices previously used.

The diameter of the outer chamber is expediently approximately 8 to 12 times larger than the diameter of the central chamber. With this design, there are appropriate flow velocities through the central chamber. Experiments have shown that the diameter of the outer chamber is expediently about 10 times larger than the diameter of the central chamber.

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It is advantageous if the inlets into the outer and the middle chamber are arranged in such a way that they bring about opposite rotational movements in the chambers. This favors heat exchange.

The invention will now be described with reference to the drawing. It shows:

Fig. 1 is a schematic representation of the system and

Fig. 2 shows a cross section through the device with the three chambers.

The plant for conditioning and sanitizing sewage sludge shown in FIGS. 1 and 2 essentially consists of the reactor 11 and the device 13. In the reactor 11, the fresh sewage sludge from the sewage treatment plant 15 is aerobic-thermophilic or thermal for about 24 hours Treated at> 60 C, after cooling in the device 13 there is a digestion in the digestion chamber 17, in which methane is produced. The methane produced in this way can be used in a known manner to drive gas engines for the generation of electricity and / or heat.

As already mentioned, the reactor 11 serves to heat the fresh sewage sludge to a temperature of> 60 C. At this temperature, the organic substances contained in the sewage sludge are hydrolyzed. This hydrolysis favors subsequent digestion and methane recovery. By raising the temperature to> 60 C for about 12 to 72 hours, the sewage sludge is also sanitized. At these temperatures worm eggs, salmonella and enterobacteria are killed.

The sewage sludge in the reactor 11 can be heated by external heat. However, self-heating, which can take place by venting the reactor 11, is particularly advantageous. The ventilation creates ideal conditions for the aerobic thermophilic bacteria, whereby their activity leads to the sewage sludge being heated to temperatures of> 60 ° C.

The device 13 has three concentric chambers 19, 21 and 23. It is important that the inlets 25, 27 and 29 are arranged tangentially. This causes the chamber contents to be rotated by the inflowing sewage sludge. As FIG. 2 shows, the inlets 25 and 29 into the outer and the middle chamber 21 are arranged opposite one another, so that they bring about opposite rotational movements in the chambers. It should be noted that both chambers 21 and 23 have an annular cross section. In contrast to a cylindrical chamber, therefore, no type of plug can form in the middle of any of these chambers, which does not or practically does not participate in the rotational movement of the chamber contents. The plug formation in chamber 19 is prevented by a sufficient flow rate of the sewage sludge.

The outer chamber 23 is connected at one end via a pump 31 and at the other end via a line 32 to the central chamber 19 to form a circuit. The contents of the two chambers 23 and 19 can therefore be circulated by the pump 31. A corresponding pump 33 is used to circulate the contents of the middle chamber 21.

The sum of the volumes of the central and outer chambers 19, 23 corresponds to the volume of the middle chamber 21. The diameter of the outer chamber 23 is approximately 8 to 10 times larger than the diameter of the central chamber 19. Good results were obtained in one embodiment of the invention achieved with a diameter of the outer chamber of 2500 mm and a diameter of the inner chamber of 250 mm and a height of the chambers of 3550 mm. The flow rate generated by the pump 31 in the central chamber 19 was about 1.5 m / s.

The line 35 connects the sewage treatment plant 15 to the device 13 via the pump 37. The line 39 connects the device 13 to the reactor 11. In the reactor 11 there is a circulation pump 41 and an injector 43 for introducing air into the sewage sludge Circulation pumping provided. The line 45 connects the reactor 11 to the device 13. From the device 13, the line 50 leads via the valve 51, the pump 33 and the valve 52 to the digester 17. The valves 51 and 58 are provided for the individual steps of the process to control. These valves are expediently controlled by a control unit 62.

The lines 59, 60 and 61 are used for ventilation. A filter 63 is provided to neutralize unpleasant smells.

In operation, the system works as follows. Fresh sewage sludge from the sewage treatment plant 15 is pumped into the outer chamber 23 by the pump 37 via the line 35 and the open valve 55. At the same time, warm sewage sludge is admitted from the reactor 11 via the line 45, the valve 53, the pump 33 and the valve 54 through the inlet 29 into the middle chamber 21. Thanks to the tangential arrangement of the inlets 27 and 29, the contents of the chambers 23 and 21 are moved as shown by the arrows in FIG. Since the pump 31 also works, sewage sludge also flows in the circuit from the chamber 23 via the pump 31 and the valve 56 into the central chamber 19 and from there via the line 32 back into the outer chamber 23.

After the chambers of the device 13 have contained the desired batches, the chamber contents are circulated. The circulation in chambers 23 and 19 has already been described. The contents of the chamber 21 are circulated via the valve 51, the pump 33, the valve 54 and the inlet 29. Thanks to this circulation, there is a rapid heat transfer from warm sludge in the chamber 21 to the fresh sewage sludge in the chamber 23. In contrast compared to the previous two-chamber system, the heat transfer time can be reduced to around half with the system described. It is also important that during the circulation in the chamber 21, the sewage sludge from the reactor 11 is largely degassed and cooled before it reaches the digester 17. This favors the digestion process in the digestion chamber 17. To drain the sewage sludge into the digestion chamber, the valve 54 is closed and the valves 51 and 52 opened, so that the pump 33 can pump the sewage sludge into the digestion chamber 17 via the line 50. In a corresponding manner, the contents of the chambers 23 and 19 can be pumped into the reactor 11 by means of the pump 31 after closing the valve 56 and opening the valves 57 and 58.

Various changes to the system are possible without departing from the basic principle of the invention. If, for example, the prevention of clogging in the chamber 21 is in the foreground, the installation of a cylindrical object 19 is sufficient. However, it is expedient to use a tube as the cylindrical object 19 which at the same time forms a central chamber and the described circulation through the center the chamber 21 allows, which contributes significantly to a better heat exchange. It would also be possible to

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Chamber 21 alternately to be treated with digested sludge from the digested area 17 and sewage sludge from the reactor 11

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send to achieve an even better heat recovery.

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1 sheet of drawings

Claims (5)

663 203 PATENT CLAIMS 1. Plant for conditioning and sanitizing sewage sludge with a reactor (11) for heat treatment, a digester (17) for receiving the heat treated sewage sludge, and a device (13) with at least three practically concentric chambers (19, 21, 23) fresh sewage sludge before introduction into the reactor (11) with hot sewage sludge from the reactor (11) or to preheat it with warm sewage sludge from the digestion chamber (17) and to cool and degas the sewage sludge discharged from the reactor (11) before being passed on to the digestion chamber (17), and pumps (31, 33) to pump the sludge in the chambers (19 , 21, 23) to circulate sewage sludge, characterized in that the inlets (25, 27, 29) are arranged tangentially in the outer and the central concentric chamber (23, 21) of the device (13) in order to prevent the chamber contents from rotating to cause the inflowing sewage sludge, and that the outer chamber (23) is connected at one end via one (31) of the pumps and at the other end via a line (22) to the central chamber (19) to form a circuit. 2. Installation according to claim 1, characterized in that the sum of the volumes of the central and the outer chamber (19, 23) corresponds to the volume of the middle chamber (21). 3. Plant according to claim 1 or 2, characterized in that the diameter of the outer chamber (23) is about 8 to 12 times larger than the diameter of the central chamber (19). 4. Plant according to claim 3, characterized in that the diameter of the outer chamber (23) is about 10 times larger than the diameter of the central chamber (19). 5. Installation according to one of claims 1 to 4, characterized in that the inlets (25, 27, 29) of the outer and middle chamber are arranged so that they cause mutually opposite rotary movements in the chambers (23, 21).