DE19617218C2 - Method and device for processing biological residues, in particular sewage sludge - Google Patents

Description

The invention relates to a method and an apparatus for processing biological Residues, especially sewage sludge.

Excess sludge from sewage treatment plants is usually dewatered using centrifuges. Despite many improvement approaches such as the use of multi-stage centrifuges or by Special designs are the drainage results of these facilities for one long-term and safe disposal of sewage sludge with partly high biological Shares unsatisfactory. Add the stabilizers such as lime or fly ash not a solution, but only increase the amount of waste to be disposed of and pollute a landfill additionally.

Also the conversion rates of biological parts of the sewage sludge into fermentation gas, as in the biological digesters downstream of a sewage treatment plant are unsatisfactory. In addition, constituents contained in the fermentation gas make electricity generation more difficult. The Digestion towers are needed, however, if the sewage sludge is used for long disposal routes must be hygienized.

The sales possibility of weakly dewatered sewage sludge in agriculture is in terms of space and quantity, the acceptance diminishes with the increase in Importance of organic farming. The disposal of sewage sludge on heaps is becoming increasingly difficult due to the high amount of biological components, even if the sewage sludge is made landfillable by quantity-increasing lean means becomes.

The use of sewage sludge as a fuel in power plants or others Incinerators require efficient drying, which is usually done in one Drying system using high-quality energy sources or the precious ones Digester gas is made from digesters. There are usually considerable transport costs for the transport of the sewage sludge to the central large plants. In addition, the proportion of sewage sludge are mostly kept low due to the sludge-specific burning and ash behavior. After all, exhaust gas cleaning for fuel mixtures is more complex than for Monofuels. For all of these reasons, sewage sludge usually has to be burned Co-payments are made.  

So far, gasification plants for sewage sludge have only been designed for large quantities, which in turn entails cost-intensive transports, since the decentralized one Sludge is only slightly drained.

From DE-A-40 20 552 a process for the utilization of sewage sludge is known in which the sewage sludge is first dried completely. In a subsequent one Degassing process at temperatures of 400 ° C to 500 ° C with simultaneous grinding Sewage sludge coke with 10 to 40% by weight of organic substances is produced as a filler is particularly suitable for asphalt.

It is therefore an object of the invention to develop a method and an apparatus with which Sewage sludge can be processed decentrally in connection with a sewage treatment plant and the optimally uses the energy contained in the sewage sludge.

According to the invention, this object is achieved by a method by the following Process steps are marked:

• - Dewatered sewage sludge is dried in a fluid bed dryer until a Water content of at most 10% is reached;
• - The dried sewage sludge is in a fluidized bed gasifier with lack of oxygen gasified, producing product gas;
• - a combined heat and power plant is operated with the product gas,
• - The waste heat from the fluidized bed gasifier and combined heat and power plant is closed Pipe systems fed to the fluidized bed dryer or the fluidized bed gasifier.

According to the invention is also a method in which the sewage sludge in a high pressure Chamber filter press is dewatered.

It is advantageous that the dewatered sewage sludge with in a mixer before drying Return material from the fluidized bed dryer is mixed and pelletized.

It is within the scope of the invention that the product gas produced in the fluidized bed gasifier is dried by condensation of the water vapor.  

It is also provided that the exhaust gas from the combined heat and power plant via heat exchangers is directed.

It also makes sense that with the filtrate running out of the high-pressure chamber filter press the water vapor from the vapors of the fluidized bed dryer is condensed.  

The device according to the invention comprises a fluidized bed dryer, a Fluidized bed gasifier and a combined heat and power plant.

A further development of the device according to the invention is that Fluid bed dryer is connected upstream of a dewatering device.

It is also expedient that the drainage device has a high-pressure Chamber filter press is.

Finally, it makes sense that means for washing the product gas are provided.

The invention has numerous advantages: by processing the sewage sludge preferably in the area of the sewage treatment plant, the volume to be disposed of is extremely reduced. Lean agents do not have to be added, only ash leaves the system.

In addition, the ash no longer contains any organic constituents, so it corresponds to the TA Municipal waste and can therefore be landfilled. This is also in epidemic hygiene Terms of importance.

Through the high drying of the sewage sludge pellets with the process heat and the Power generation, which (with dry residue values over 40% in the filter cake) up to The process can be used to cover the entire electricity needs of the sewage treatment plant energetically optimal. It can only be used with renewable raw materials (sewage sludge, optionally biodiesel or other renewable fuels) as CO₂ neutral Process operated.

The following is an exemplary embodiment of the method and the Device according to the invention described in detail with reference to a drawing. It shows

Fig. 1 is a schematic representation of the device according to the invention.

The sewage sludge 10 coming from the sewage treatment plant is pressed into a high-pressure chamber filter press 37 via a high-pressure pump and dewatered there. This sewage sludge is usually excess sludge conditioned only with polymers with a dry residue (TR) of approx. 2-8%. In the high-pressure chamber filter press 37 , the sewage sludge is preferably dewatered to a TR value of more than 40%, since the plant can work energy self-sufficiently at TR values of more than 40%. Due to the short dewatering times and the TR values that can be achieved, relatively small high-pressure chamber filter presses 37 are sufficient to dewater the resulting sludge quantities.

The filter cake is thrown into an intermediate store 11 in order to compensate for the batch operation of the high-pressure chamber filter press 37 . The pre-classified filter cake pieces reach the mixer 13 via a conveyor device 38 and a filter cake shredder 12 . Pellets are formed there.

These pellets are whirled in a fluidized bed dryer 14 and dried to TR values of over 90% by heat introduced via closed steam circuits 19 , 31 . The dry matter is classified in a sieve 16 , then heat is extracted from the dry good in the product cooler heat exchanger 39 and the dry good is temporarily stored in a dry goods storage 40 (eg with N 2) which can be rendered inert.

The pellets are pressed into a fluidized bed gasifier 17 via a further conveying device, and the biological components (loss of ignition of the dried pellets: approx. 50%) are gasified at temperatures of 850-900 ° C. under a lack of oxygen. This prevents the formation of NO compounds. A water vapor lance can also be provided in the fluidized bed gasifier 17 . The mineralized ash 18 is driven off by transport vehicles; it can be deposited. The solid constituents are separated from the resulting product gas in filters 34 , 20 and the gaseous constituents are condensed out of the product gas (e.g. mercury) in product gas-steam heat exchanger 3 , product gas heat exchanger 6 and condensation heat exchanger 5 , with this being the case in condensation heat exchanger 5 Product gas is dried by condensation of the water vapor still contained.

The product gas-steam heat exchanger 3 and the product gas heat exchanger 6 are by suitable devices, for. B. steam sootblower cleanable to achieve better heat transfer and to avoid deposits and incrustations. In order to obtain a uniform product gas quality and for pressure compensation, a pressure compensation mixing container 41 is installed in front of the condensation heat exchanger 5 . If necessary, the pressure compensation mixing container 41 is also used as a washing column for the product gas. The liquids possibly occurring in the pressure equalization mixing container 41 are conducted and cleaned via a condensate 43 into the cleaning system 42 .

The product gas is burned in a combined heat and power plant 21 , consisting of an engine M and a generator G for power generation, the waste heat of the engine being transferred in normal operation via an engine cooling water heat exchanger 7 .

The exhaust gases of the engine are passed to a chimney 22 via a catalytic converter Kat, if necessary via an additional oxidizing catalytic converter 36 , an exhaust gas supply air heat exchanger 1 , a steam exhaust gas heat exchanger 2 , a further exhaust gas heat exchanger 9 and an exhaust gas fan 32 .

Selected from the high pressure chamber filter press 37 running filtrate 26 and during the discharge of the high pressure chamber filter press 37 and the hot water 25 serve to condense in the condensing heat exchangers 4 and 5. FIG. The condensates 29 , 30 , 43 prevent vapors or gases from leaving the system.

The solid particles are released from the slightly superheated steam released in the fluidized bed dryer 14 during drying in a steam cloth filter 15 and the heat is extracted from drying vapors 8 in a condensation heat exchanger 4 and a precooler. The condensate that runs off is returned via the condensate 29 into the filtrate outlet 24 to the sewage treatment plant, with accompanying substances being precipitated and / or broken down in a treatment plant 23 as required.

The return material from the sieve 16 and the steam cloth filter 15 is mixed in the mixer 13 with the filter cake pieces and pelletized. By using the return material, fluctuations in dry matter in the filter cake can be compensated for during dewatering.

The condensed water from the cooler 5 is likewise returned via the condensate 30 into the filtrate outlet to the sewage treatment plant, with accompanying substances being precipitated and / or broken down in the cleaning plant 23 as required.

The supply air 27 to the fluidized bed gasifier 17 is fed through an air supply fan 35 through product cooler heat exchanger 39, product gas heat exchanger 6, the aforementioned engine cooling water heat exchanger 7, precooler drying vapors 8 and engine exhaust gas heat exchanger 9, wherein depending on the system all of these heat exchangers 39, 6, 7, 8, 9 or only individual or none at all. At least the presence of an exhaust gas supply air heat exchanger 1 is expedient. These measures can increase the supply air temperature to over 500 ° C, which in turn increases the thermal efficiency of the device and significantly improves the gas quality of the product gas.

The fluidized bed dryer 14 is connected to the product gas / steam heat exchanger 3 and the steam / exhaust gas heat exchanger 2 via closed steam heating circuits 19 , 31 . With the waste heat, which normally serves to heat the supply air 27 , the mixture can also be preheated by fogging the mixer 13 or local heat can be coupled out.

The auxiliary energy for the cogeneration unit 21 , in particular when starting up, is taken from a decentralized energy store 28 , which is preferably filled with renewable energy sources such as biodiesel.

As already stated, the device works at TR values over 40% in the dewatered Sewage sludge self-sufficient, d. that is, electricity to operate the sewage treatment plant and / or heating can be delivered.

In connection with newer processes for the biology of the wastewater treatment plant, already introduced to which the carbon is stuck in the sewage sludge instead of already in the aeration tanks To be blown into the air, the invention opens up the possibility of the energy yield from the sewage sludge.

Claims (10)

1. Process for processing biological residues, in particular sewage sludge, characterized by the following process steps:

• - dewatered sewage sludge is dried in a fluid bed dryer until the water content is at most 10%;
• - The dried sewage sludge is gasified in a fluidized bed gasifier with lack of oxygen, producing product gas;
• - a combined heat and power plant is operated with the product gas,
• - The waste heat from the fluidized bed gasifier and combined heat and power plant is fed to the fluidized bed dryer or the fluidized bed gasifier via closed pipe systems.

2. The method according to claim 1, characterized in that the sewage sludge in one High pressure chamber filter press is dewatered. 3. The method according to claim 1 or claim 2, characterized in that the dewatered sewage sludge before drying in a mixer with return material from the Fluid bed dryer is mixed and pelletized. 4. The method according to claim 1, characterized in that in the fluidized bed gasifier resulting product gas is dried by condensation of the water vapor. 5. The method according to claim 1, characterized in that the exhaust gas of the Combined heat and power plant is passed through heat exchangers. 6. The method according to claim 2, characterized in that with the from the high pressure chamber filter press draining off the water vapor from the vapors of the Fluid bed dryer is condensed. 7. Device for performing the method according to claims 1 to 5, characterized characterized in that the device comprises a fluidized bed dryer, a Fluidized bed gasifier and a combined heat and power plant.   8. The device according to claim 7, characterized in that the fluidized bed dryer a drainage device is connected upstream. 9. The device according to claim 8, characterized in that the Drainage device is a high pressure chamber filter press. 10. The device according to claim 9, characterized in that means for washing the Product gas are provided.