DE3234362A1 - Process and apparatus for drying previously dewatered sewage sludges - Google Patents

Abstract

With the aim of removing residual water from previously mechanically dewatered sewage sludges in a simple and economic manner to give about 100% dry matter (DM) with disruption of the capillary forces of the cells of the solids, in a first process step, the previously dewatered sewage sludge is stirred, tumbled and/or kneaded with continuous mass circulation. At the same time, the product temperature is increased to about the boiling point of the mixture. In a second process step, the vapours obtained on the one hand are condensed and in a third step the dry matter obtained on the other is burnt to obtain the process heat to increase the product temperature (first process step).

Description

Method and device for drying

pre-dewatered sewage sludge The invention relates to a method and a device for drying pre-dewatered sewage sludge, an important one Part of the treatment of municipal and industrial wastewater is the disposal of the Substances separated from the wastewater in the course of wastewater treatment. These lie in the form of sludge with a high water content with 95 to 99% water content. Generally we speak of sewage sludge that is biological from primary and secondary clarifiers Sewage treatment plants, aeration basins, precipitation stages and the like. Wastewater treatment plants come. For a rational disposal of this sludge is an essential reduction the water content to reduce the volume of the sludge and to change the consistency necessary. As sludge treatment measures to reduce the water content A distinction is made between thickening, drainage and drying. So can the water content of digested sewage sludge from municipal sewage through thickening up to about 95 to 90%, through ntw # ssung Depending on the method used, up to Reduce to approx. 40 to 75% and by drying to approx. 40 to 30%. today the final water content of sewage sludge that can be achieved with these dewatering processes regarded as too small, as there is no longer a sufficient number of landfill clearances is. Landfilling is now an economic / technical as well as ecological problem. As a solution to the problem, there is another drainage system the sewage sludge by way of sludge drying with subsequent composting and incineration processes. For example, drying using a rotary drum dryer known who however, disadvantageously especially with regard to emissions that are harmful to the world require a high level of technical effort. Also is at With this method, the energy required to be applied can only be used extensively. The resulting wells must have appropriate washing systems, the enormous smoke gas volumes be cleaned using effective dust extraction systems.

Which, on the other hand, has sludge incineration as a possible solution to the problem also have the major disadvantage that additional fuels are required, with the effort to be made depends on the water content and calorific value of the sewage sludge. The fluidized bed furnace, which is often used as a furnace type, works with temperatures between 4500 C and 11500 C, so that a considerable use of natural gas or heating oil as an additional fuel is required. Another disadvantage is the high level of equipment Expenditure. Many parts of the system are fire-resistant or fire-resistant and must be created there are complicated preheating devices, inflow floors with special nozzles, devices required for air distribution, afterburning rooms and recuperators. The apparatus Effort is an inevitable consequence of what is only imperfect according to the state of the art Pre-drainage and drying of the sewage sludge.

The invention is based on the object of mechanically pre-drained Sewage sludge, avoiding the above-mentioned disadvantages in a simple and economical way Way up to 100% dry matter (DM) breaking the capillary forces of the Solid cells to drain residual water.

The object is achieved according to the invention in that the pre-drained Sewage sludge in a first process stage with continuous mass circulation is stirred, drummed and / or kneaded and at the same time the product temperature is about that is raised to the boiling point of the mixture in a second Procedure stage the vapors obtained on the one hand are condensed and that in a third Process stage the dry substance obtained on the other hand for the recovery of process heat is burned to increase the product temperature. With this procedure after the invention can pre-dewatered sewage sludge up to 100% dry matter (TS) residual drainage. This is not only due to the mechanical drainage the accumulated surface water is deposited, but also the remaining cell-bound water Water, which so far has been an insoluble problem for all decanter systems. Through the combined action of the stirring, milling and / or kneading process, a working temperature approximately at the height of the boiling point of the mixture and, if necessary, the addition of an aromatic and / or solvents containing aliphatic hydrocarbons in the second Process stage, the capillary forces of the solid cells are broken, so that this water content is also separable.

The pre-drainage expediently takes place mechanically on dry matter values from 25% TS to 50% TS instead, so that the treatment according to the invention a pasty Based on mass.

According to an expedient embodiment of the invention, it is proposed that to carry out the treatment of the sewage sludge under vacuum conditions. Through the When applying negative pressure, the required boiling temperature is significantly reduced, so that economic advantages result without the success of the combined Effects of mechanical treatment, temperature and possibly solvents in question is provided. The energy balance becomes considerable through a negative pressure treatment Extensively improved. Depending on the type of solvent from the group the aromatic and / or aliphatic hydrocarbons and the amount of the used Product temperatures of the mixture between 600 ° C. and 2000 ° C. can expediently be reduced to a vacuum be.

The device according to the invention for carrying out the drying process is characterized by a reactor vessel with a feed for the sewage sludge, possibly a feed for the solvent, a heating device, an agitator, a discharge for the vapors into a distillation receiver and a discharge for the dehydrated product.

The vapors are expediently carried out for thermal preconditioning via jacket pipes of the sewage sludge supply line, so that by utilizing the heat content the sewage sludge is tempered in a simple manner before it is introduced into the reactor can be.

A heat exchanger can be installed between the reactor and the distillation receiver be arranged, the heat transfer medium, in particular heat transfer oil, in circulation to a Tube furnace with multi-fuel burner is available, to which, if necessary, an evaporator for the solvent is connected and to which the dehydrated product can be fed for firing. This means that the sewage sludge is dewatered in a closed apparatus System and are environmental pollution in the reactor area Completely locked out. The released water is separated and can be used as service water used or introduced into any receiving water while the solvent is used in the continuous cycle in order to minimize the loss of active ingredients. The use of the dehydrated product in the tube furnace is, inter alia. advantageous because all im Solids remaining amounts of solvent get into the combustion chamber of the furnace and burned there so that, according to the energy balance, only for starting up the system additional primary energy must be used.

In the preferred embodiment there is also a vacuum device provided and the heating device of the reactor is also attached to the tube furnace connected.

Further details, features and advantages of the subject invention result from the following description of the associated drawing in which schematically a system according to the invention for drying pre-dewatered sewage sludge is shown, the drawing shows: Fig. 1 a sewage sludge drying plant in Form of a flow diagram, FIG. 2 shows the system of FIG. 1 as a flow diagram in plan view, Fig. 3 shows a reactor in longitudinal section and Fig. 4 shows a system scheme.

A major part of the plant are six reactors connected in parallel 6, 6a; 7, 7a; 8, 8a, which are constructed in detail according to FIG. 3 of the drawing. The reactors 6 to 8 have connections 14 in the upper area, which make the connection to a main pumping line 16 through which sewage sludge from a wagon 17 over a Transport line 5 is pumped to the reactors. Depending on the consistency, a screw conveyor can also be used to feed sewage sludge Find use. In the exemplary embodiment, however, a pump line 16 is used, which is designed as a jacket tube and has the possibility of using the Heat content of the vaporous water-solvent mixture emerging from the reactors to preheat the sewage sludge.

In the lower area of each reactor 6 to 8 there is a connection 18 for the supply of a solvent consisting of aromatic and / or aliphatic Hydrocarbons. For this purpose, injection nozzles are not shown in detail provided in the bottom of each reactor. The solvent is pumped over and a pipe 19 taken from a tank 4. In an evaporator 3 this is Solvent heated above its boiling point to about 1500 C and thus in shape a solvent vapor is injected through the reactor bottom. The evaporator 3 is connected to a tube furnace 2, which is in coils from an expansion tank 1 containing thermal oil. This thermal oil is not only used for heating of the evaporator 3 but also used for the heating device of the reactors. Of the The closed circuit of the heat transfer oil is indicated by the flow diagram with arrows provided lines, which represent pipelines, can be seen. So it will be down introduced into the reactor housing designed as a heating jacket and in the upper area removed again.

Each reactor 6 to 8 also contains a stirrer for constant circulation of the mass until the sewage sludge used is completely drained. Find as agitator preferably cross bar stirrer 20 with edge scraper use.

There are two at each reactor for the discharge of the treatment products further connections formed. There are centrally located in the ground Floor outlets 21, via which the dehydrated product is transferred to a storage container by means of screw conveyors 13 can be transported. r the sewage sludge dewatered in this way with the adhering to it Residual solvent has a sufficient calorific value to be burned, is the storage container 13 attached to the tube furnace 2 to the multi-fuel burner burned to generate the amount of heat required to heat the thermal oil will. Since the commissioning of the plant and also calorific value fluctuations under certain circumstances require the use of primary energy, the storage tank 13 is a mixer 15 downstream, by increasing the heating from the sewage sludge with coal dust originating dry matter can be passed through, from each reactor 6 to 8 a water vapor / solvent mixture must also be discharged. There are pipe connections for this 22 in the ceiling area of each reactor is provided, which the water vapor-solvent mixture Pass this pipeline via a heat exchanger 9 into a distillation receiver 10 is combined as a jacket pipe with the pump line 16 for the purpose of preheating the pre-drained Sewage sludge.

The water vapor / solvent mixture condenses in the heat exchanger 9. In the distillation receiver 10, the separation of the constituents takes place, so that on the one hand solvent is fed from there from the tank 4 and on the other hand Water reaches a receiving water via a water separator 11. Using the right In Fig. 1 of the drawing shown vacuum pump 12, it is possibly the entire system to be vacuumed to 20% atm, so that the system operated with comparatively low temperatures The system described is supplied with a starting product that in most cases a sewage sludge with dry matter values # between 1 and 10 % TS is. This sewage sludge is mechanically to dewater, so that a pasty Mass of 25 to 50% TS is present This product is then over the conveyor belt 5 fed to the thermal fusion system and there up to about 100 fi TS residual drained.

This treatment is carried out in reactors 6 to 8, which the combined use of solvents based on aromatic or aliphatic hydrocarbons with a working temperature equal to the boiling point of the mixture. In addition the pre-dewatered sewage sludge via the pump line 16 into the reactor vessels promoted, with a proportion of solvent via an admixing nozzle before the product enters (not noticeable) can be injected.

The sewage sludge is first in the reactor vessels via the heating jacket with constant stirring to a temperature below 140 @ C, approximately to the boiling point of the mixture, brought. In doing so, the system is raised to 20 by means of the vacuum pump 12 % at vacuumed, whereby the injection nozzle # in the bottom of the reactors vaporous solvent bring in. With the agitators, the constant circulation of the mass is achieved until it is complete Drainage ensured.

The solvent vapor injected from the bottom of the reactor lifts the Capillary forces within the pre-drained sewage sludge, so that the cell-bound Water is suflossen and together with the solvent vapor as a water vapor-solvent mixture can be discharged. The mixture then condenses in the heat exchanger instead of and finally a separation of the two components of the mixture from one another # The remaining solvent is fed back into the process.

The dehydrated dry product is after pressure equalization of the reactors 6 to 8 via the bottom outlets and screw conveyors into the storage tank 13 transported and finally burned in the tube furnace. As an end product to be dumped8 all that remains is the ashes.

The system shown in Fig. 2 of the drawing works in principle like the one already described, but includes the possibility of expansion to approx. 70,000 Tons of dry matter per year through the additionally provided reactors 6a> 7a and 8a.

LIST OF REFERENCES: 1 expansion tank for (1r heat transfer oil 2 tube furnace 3 evaporator 4 tank 5 transport line 6, 6a reactors 7, 7a reactors 8, 8a reactors 9 heat exchangers 10 distillation receiver 11 water separator 12 vacuum pump 13 Storage container 14 Connection i5 Mixer TS / 95 - pulverized coal 16 Pump line 17 Carriage for pre-dewatered sewage sludge 18 connection solvent 19 pipeline 20 cross-beam agitator 21 floor outlets 22 pipe connections

Claims (12)

Claims 1. Method for drying pre-dewatered sewage sludge, in that it is in a first stage of the process is stirred, drummed and / or kneaded with continuous mass circulation and at the same time the product temperature is increased to about the boiling point and that in In a second process stage, the vapors obtained on the one hand are condensed and in a third process stage the dry matter obtained on the other hand burned to generate process heat to increase the product temperature will. 2. The method according to claim 1, characterized in that in the first Process stage one containing aromatic and / or aliphatic hydrocarbons Solvent is added, in the second stage in connection The solvent condenses with the vapors and the process is re-separated is supplied, 3. The method according to claim 1 and 2, characterized in that the Sewage sludge to be dried is pre-dewatered to dry matter values of 25% DM to 50% DM will. 4. The method according to claims 1 to 3, characterized in that that the treatment of the sewage sludge is carried out under vacuum conditions. 5. Process according to claims 1 to 4, characterized in that that the product temperatures of the mixture set between 600 C and 2000 C. will. 6. Device for performing the method according to the claims 1 to 5 characterized by a reactor vessel with a feed for the sewage sludge, possibly a feed for the solvent, a heating device, a stirrer, Fulling or kneading mechanism, a discharge for the vapors into a distillation receiver (10) and a discharge for the dehydrated product. 7. Apparatus according to claim 6, characterized in that the guide of the vapors takes place via jacket pipes of the sewage sludge feed line. 8. Device according to claims 6 and 7, characterized in that that between the reactor and the distillation receiver (10) a heat exchanger (9) is arranged, the heat transfer medium, in particular oil heat transfer medium, in circulation a tube furnace (2) with a multi-fuel burner, to which an evaporator (3) for the solvent is connected and that for firing the dehydrated product is feedable. 9. Device according to claims 6 to 8 characterized by a Vacuum device. 10. Device according to claims 6 to 9, characterized in that that the heating device of the reactor is also connected to the tube furnace (2) is. 11. Device according to claims 6 to 10, characterized in that that the supply of the solvent into the reactor via injection nozzles arranged in the floor is provided. 12. Device according to claims 6 to 11, characterized in that that the agitator is a cross bar agitator (20) with an edge scraper.