DE2950324A1 - Solid fuel prodn. from waste materials - by low-temp. pyrolysis - Google Patents

Abstract

Prodn. of solid fuel from waste materials (esp. comminuted domestic refuse) is carried out by a process in which the fuel is obtd. in a form suitable for use in conventional combustion equipment (esp. in powder form), with the improvement that the waste material is first subjected to low-temp. pyrolysis. The process is superior to prior art processes w.r.t. environmental acceptability, thermal efficiency and equipment costs. More specifically, it is easier to remove Cl- and F-contg. pollutants from the small amt. of low-temp. pyrolysis gas than from large amts. of high-temp. pyrolysis or combustion gases.

Description

Description The invention relates to a method of manufacture solid fuel from waste, in particular from pre-shredded household waste, in which the fuel is suitable for conventional combustion systems, preferably powdery form.

The disposal of waste, especially household waste, is due to the growing population and the depletion of landfills is an ever more urgent issue Problem. Since the fuel costs for power plants also rise at the same time, lies it suggests that waste should be processed so that it can be used as fuel. A corresponding process for the treatment of organic waste materials and that The product obtained is described in DE-OS 25 13 767. This method however, leads to a high environmental impact when burning the fuels produced and, moreover, does not result in optimal utilization of those contained in the waste Carbon constituents.

It is the object of the invention to provide a method and a device for Recycle waste, in particular household waste, that is known to the Process in terms of environmental harmlessness is superior and at the same time a results in higher energy yield. Furthermore, the investment costs of the processing plant be lowered.

The object is achieved in that the waste first by a Low temperature pyrolysis process is degassed.

By degassing as part of a low-temperature pyrolysis process Immediately after pre-shredding, further processing can be degassed on one and dried product that does not require any further drying or chemical processing is more necessary. The gas produced, also only low Temperatures can be compared to high temperature pyrolysis or combustion processes easier to clean of the harmful chlorine and fluorine components, because the amount is significantly less. There is also no cooling before the deposition necessary. This results in a process that leads to reduced environmental pollution and has low investment costs and good energy efficiency.

In an embodiment of the invention it is provided that the pyrolysis process between 1500 C and 4500 C, but especially between 2500 C and 3500 C. The temperature range from 1500 C to 4500 C has been found for the pyrolysis process according to the invention found to be advantageous, with 0 0 between 250 ° C. and 350 ° C. being in particular C a sufficient but not too great degassing of the waste, if it is is household waste, L results. At 2500 C - 3500 C this results from normal household waste an application of solid residue of 50% - 70%, an average of 60 96 and a Output of gas of 20, - 35 96, on average of approx. 27.%, the difference amount between solid residue and gas consists of tar / oil and water. An output of solid carbon averaging 60% is an unprecedented high yield, which is one of the reasons for the particular cost-effectiveness of the process.

In an embodiment of the method it is provided that in the pyrolysis process Gas with at least sufficient heat content for the pyrolysis process to proceed is generated, the pyrolysis process by the heat content of the gas generated is maintained. In this way it is particularly advantageous that no external energy for heating or for the processing of the waste to maintain the Pyrolysis process is required. The pyrolysis process is self-sustaining in terms of heat consumption! Additional heating or drying energy is not needed. The processing plant only needs electrical energy to Drive of the pyrolysis drum, the conveying devices, blowers, sieves, sifter, etc. However, the consumption of electrical energy is much lower than the energy recovered when the fuel produced is burned in power plants so that the overall energy balance is very positive.

In a further embodiment of the invention it is provided that from the gas generated in the pyrolysis process, chlorine and fluorine, preferably dry, deposited will. By the passage of chlorine and fluorine from the waste into the pyrolysis gas, from which it is deposited again according to the invention advantageously results in a reduced chlorine and fluorine emissions from the power plant in which the fuel is produced is finally burned. When the fuel produced is mixed with conventional fuel Fuels with small proportions of chlorine and fluorine, e.g. to lignite, result a total of chlorine and fluorine emissions that are below the permissible limit values lies. So it emerges about the simple and advantageous at low Volume throughput performed chlorine and fluorine separation within the processing plant, a significant improvement in the use of waste-derived fuel.

In a further embodiment of the invention it is provided that the at the pyrolysis process generated gas after the chlorine-0 and fluorine separation at a Temperature of more than 1000 C is burned. By burning in the temperature range above 10,000 C, this can also be done with the pyrolysis lean gas by preheating the combustion air be achieved, it is advantageous that in the combustion chamber and the downstream Pipeline certainly does not have the dew point even for aggressive gas components is fallen below. It can therefore be made using conventional inexpensive materials and piping systems are being worked on.

In a further embodiment of the method it is provided that the degassing After the pyrolysis process, waste is subjected to Fe and other heavy material separation as well as processed into powdered fuel. The ones during the pyrolysis process because of the implementation in the low temperature range only dried and. Otherwise unchanged constituents of Fe, Cu, Al etc. are as well as glass and stones separated from the fuel by the heavy material separation, so that a fuel is advantageously obtained which consists only of carbonaceous material consists. Excretion is particularly problem-free because of the pyrolysis treatment the waste behind the pyrolysis device is anhydrous, dry and easy to handle is present. For use in the power station after the separation of Fe and other Heavy material fractions carried out a comminution in a grinding circuit, which the Brings fuel to a fineness that can be burned with normal dust firing.

In this way, the fuel generated can be used particularly advantageously in existing, conventional large power plants are burned and it does not need to be in terms of efficiency used poor grate firing of old power plants or waste incineration plants to become. The use as power plant fuel is for the pyrolyzed waste the main use of the invention.

To carry out the manufacturing process for fuel from waste, in particular from household waste, a system / device is provided that has an externally heated Low temperature pyrolysis device, preferably a cross-flow heated pyro lysis drum. With such a pyrolysis device according to the invention The method can be carried out advantageously.

In an embodiment of the device it is provided that the pyrolysis gas outlet end the pyrolysis device with a combustion chamber and furthermore with the heating side the pyrosysis device is connected via a return line.

In this way, a heating gas circuit is advantageously obtained, in which the gases generated in the pyrolysis device are burned and returned for heating the pyrolysis device L are used, so that according to the invention advantageously none External heating or drying energy must be used. It is intended that that in front of the combustion chamber an HCl rock separator, which preferably also separates fluorine, is arranged. This advantageously ensures that the treatment plant does not contain any chlorine and emits no fluorine and that also no waste water containing chlorine and fluorine accrues. It should be noted that the sewage problem is a major problem in gas generating plants who work on household waste.

In a further embodiment of the invention it is provided that for the recirculated and burned gases behind the pyrolysis device an exhaust gas heat exchanger is arranged for heating the combustion air of the combustion chamber. To this Way is advantageously achieved that the energy that at the pyrolysis set will be used as much as possible for the reprocessing process comes and continues to reach the combustion temperature in the combustion chamber despite the use of lean gas and the relatively low gas yield by the Low temperature pyrolysis is above 10000 C.

In a further embodiment of the invention it is provided that behind the pyrolysis device for the degassed waste a Fe- and Schwergutabscheidevorrichtung and a grinding and sieving device is arranged. So one becomes beneficial Treatment of the pyrolysed waste achieves the final use of the waste in conventional large power plants. Overall, there is an efficiency satisfactory, leading to an unprecedented positive energy balance Use of the waste.

The invention is illustrated using a schematic process tree explained in more detail, from which further advantageous details can be found. the Individual devices already known in the art, such as pyrolysis drum, combustion chamber etc. are shown in the process tree as labeled blocks.

The household garbage delivered arrives according to the double arrow 0'- first in a pre-shredding device 1, e.g. a chain hammer mill, which A good breakdown of the various waste components causes, but brittle Do not crush materials such as glass and stones too far.

The pre-shredded material comes from the pre-shredding device 1 Waste according to the arrow 1 in the pyrolysis device 2, here an externally heated one Pyrolysis drum, in which it can be heated to at least 1500 C and at most 4500 C, to 0 preferably 250 C - 350 C, heated and pyrolytically decomposed in the process will. The resulting volatile products are shown according to arrow 2 " withdrawn from the pyrolysis device and preferably by dry route from hydrogen chloride and hydrogen fluoride purified. The dry washing of flue gases for removal the pollutant gases HCl and HF have already been tested in waste and hazardous waste incineration.

The HOl and HF fall from the dry washing process in salt form and can can easily be dumped or re-used after cleaning.

The cleaned gas passes from the flue gas cleaning device 3 according to the arrow 3 "in the combustion chamber 4, where it is preheated together with the Combustion air 5 ″ which has been preheated in the exhaust gas heat exchanger 5 is burned will. The combustion chamber 4 leaves the burned gas as heating gas at temperatures over 10,000 C. This destroys all organic ingredients, so that the resulting smoke gases only contain steam, carbon dioxide and nitrogen. Via the heating gas line, represented by the arrow 4 ″, the heating gas arrives at the Heating zone 2a of the pyrolysis device 2, which is preferably a double-jacket drum is formed, and generates the necessary pyrolysis temperature here to the pyrolysis to keep going continuously.

After leaving the heating zone 2a of the parolysis device 2 the gas reaches the exhaust gas heat exchanger 5 according to the arrow 2a ", where it is the gives off the last usable heat. With an exhaust gas temperature below 2000 C it leaves this Heat exchanger and is fed to a chimney without requiring any further cleaning.

The discharge of solid residues from the pyrolysis device 2 takes place according to the arrow 2 '. An inside and, for example, serve as the discharge conveyor externally cooled screw conveyor, which at the same time provides the necessary air seal results, but discharge scraper conveyors with rotary feeders etc.

can be used because the waste is already dry and non-sticky, present in lump form as a solid residue.

I Without further drying or heating being necessary, the solid residue is now mechanically processed further, initially one Iron separation takes place, for example, in a magnetic separator 6, which is sifted e.g. in a zigzag wind sifter, but also on an air cooker, in which the non-magnetic inert component e.g. glass, stones, Cu and Al sheets as heavy Fraction to be deposited.

This inert component can once again affect the valuable materials Cu, Al, etc. for which one of the well-known sorting processes, e.g. heavy beet processing can be used.

Subsequent to the sighting in the sighting device or the air stove 7, the solid residue component, which now only contains C, enters the shredding device 8, to which a screening or fine sifting 9 is advantageously connected, which together forms a grinding circuit with the comminuting device 8 via the return 9 '. This ensures that actually n4r fuel of the desired fineness e.g. the fineness, as necessary for dust firing, is produced.

The finished fuel leaves the plant according to arrow 10 '. The transport can e.g. by silo vehicles etc.

happen because the fuel can now be pneumatically conveyed without any problems is present.

The fuel produced has a calorific value of about 4200 kcal / kg, where the yield of fuel is based on one ton of average household waste is around 290 kg. The incombustible inert component, which is about 25 percent by weight of the waste used is to be added, but in volume because of its much higher Density is significantly lower, can safely be dumped or in road construction can be used.

Overall, the method according to the invention results in t.

and use of the device according to the invention a recovery of Waste, especially household waste, with a higher energy utilization than previously known. With the known pyrolysis processes, the energy utilization can be set at around 40% are, while here 55% - 60, of the energy introduced into the process in the finished product Product is available.

L The result is a solid end product, which in terms of calorific value and in other Burning behavior roughly corresponds to that of hard lignite and accordingly problem-free and can be stored, transported and burned inexpensively.

It is also particularly advantageous that no waste water is produced. This is consistently a major problem in pyrolysis processes.

Compared to the production of fuel without the pyrolysis according to the invention the result is a significantly reduced amount of chlorine and fluorine in the fuel, one Bring an increase in total energy and the saving of an embrittling agent. All in all the method according to the invention results in a method that is similar to the previously known Waste treatment process, both the pure pyrolysis process and the process for the production of fuel without pyrolysis in terms of economy and is superior to the low environmental impact.

Claims (13)

Process for the production of a solid fuel from waste, especially from household waste. l Claims 1. A method for producing a solid fuel from waste, especially from pre-shredded household waste, in which the fuel in a form suitable for conventional firing systems, preferably in powder form accrues that the waste is initially through a low temperature pyrolysis process is degassed. 2. The method according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the pyrolysis process between 1500 C and 4500 C, but in particular between 2500 C - 3500 C, expires. 3. The method nh claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that gas with at least sufficient heat content in the pyrolysis process is generated for the progress of the pyrolysis process. 4. The method of claim 1, 2 or 3, d a d u r c h g e -k e n n z, e i c h n e t that the pyrolysis process by the L heat content of the gas generated is maintained. 5. The method of claim 1, 2, 3 or 4, d a d u r c h g e k e n nz e i c h n e t that from the gas generated in the pyrolysis process, chlorine and Fluorine, preferably dry, is deposited. 6. The method of claim 1, 2, 3, 4 or 5, d a d u r c h g e k It is noted that the gas generated during the pyrolysis process after the chlorine and the fluorine deposit is burned at a temperature of more than 10,000 ° C. 7. The method of claim 1, 2, 3, 4, 5 or 6, d a d u r c h g e it is not stated that the degassed waste after the pyrolysis process is a Subject to Fe and other heavy material separation, as well as to powdered fuel be processed. 8. The method according to any one of the preceding claims, d a -d u r c it is noted that the degassed waste is used as fuel, in particular in power plants. 9. Device for carrying out the manufacturing process for fuel from waste, in particular from household waste, according to one of the preceding claims, d u r c h e k e n n n n e i nt e i n e t that they have an externally heated, low-temperature pyrolysis device, preferably a cross-flow heated pyrolysis drum (2). 10. The device according to claim 9, d a d u r c h g e k e n n -z e i c h n e t that the pyrolysis gas outlet end of the pyrolysis device (2) with a Combustion chamber (4) and further with the heating side (2a) of the pyrolysis device is connected via a return line (2 ", 3", 4 "). 11. The device according to claim 10, d a d u r c h g e k e n n -z e i c h n e t that in front of the combustion chamber (4) an HCl dry separator (3), which is preferably also separates fluorine, is arranged. 12. The apparatus of claim 9, 10 or 11, d a d u r c h g e k e n n z e i n e t that for the recycled and burned pyrolysis gases behind the pyrolysis device (2) an exhaust gas heat exchanger (5) for heating the combustion air the combustion chamber (4) is arranged. 13. Device according to one of the preceding claims 9 to 12, d a d u r c h g e k e n n n z e i c h n e t that behind the pyrolysis device (2) for the degassed waste an Fe and heavy material separator (6,7) and a grinding and sieving device (8,9) is arranged. - Description -