FR2683467A1 - PROCESS FOR THE TREATMENT AND DESTRUCTION OF DOMESTIC AND / OR INDUSTRIAL WASTE AND FUEL MANUFACTURED FROM SUCH WASTE. - Google Patents

Abstract

Process for processing and eliminating combustible solid, liquid or pasty waste (1), in which said waste is first sorted, the combustible solid waste (5/7) is then ground, while part (2k) of the plastic waste is liquified by immersion in a solvent bath (10); the ground waste is blended with the liquified plastic waste (11) and other liquids and a plurality of elements (14) is produced from the pasty composition so obtained. The elements are dried by heating (15) in order to obtain a plastic-coated fuel. Said fuel (16) is destroyed by burning at a high temperature in a closed vessel (20/23), supplied with atmospheric air (25) or pure oxygen (26).

Description

Process for the treatment and destruction of household waste and / or
industrial and fuel made from such waste.

 DESCRIPTION.

 The subject of the present invention is a method for treating and destroying domestic and / or industrial waste and a fuel made from such waste.

 The technical sector of the invention is that of installations, apparatus and processes used for the reception of household and industrial waste, the recovery of certain non-combustible products and the destruction of other waste, in particular household waste.

 The destruction of household or industrial waste is a well-known problem, the solution of which is currently applied is both costly and polluting, on the one hand in terms of gaseous discharges from combustion and, on the other hand in terms of solid, non-combustible and non-recyclable waste. Certain ferrous waste, steels, or copper-based waste such as bronzes, brasses or other non-ferrous, such as aluminum alloys for example, can be recovered for reuse.

 This recovery activity is well known today.

 The other non-recoverable waste cannot, to a very large extent, be recycled and is generally dumped on storage areas awaiting burning. The accumulation of this waste, the production of which is daily, makes it become over time, particularly bulky and polluting, in particular those reputed to be non-biodegradable, such as plastics or elastomers for example. The question of highly polluting liquid or pasty toxic products, such as acids, bitumens, tars and other such wastes, also pose a major problem for their elimination.

 So-called household waste incineration centers are known, in which combustible waste is eliminated by combustion. However, the release of gases and fumes takes place in the atmosphere and, as a result, contributes to air pollution and the deterioration of the environment.

 The incineration plants currently in operation therefore release gases and fumes from the combustion of said waste into the atmosphere, of which we know that the most harmful and polluting are carbon monoxide and nitrogen oxides.

 The present invention aims to provide a radical and ecological solution to the destruction of combustible household and industrial waste.

 A first objective of the invention is to destroy domestic and industrial waste of all kinds, solid, liquid, pasty or gaseous, under conditions favorable to the environment, by discharging low-polluting gases into the atmosphere.

 A second objective is to produce from said waste a fuel which, while allowing their destruction by combustion, ensures a calorific power such as to produce economically, an energy usable for domestic or industrial purposes.

 Another objective is that this fuel is stable over time in order to allow its prolonged storage and its handling, in particular by mechanized means.

These objectives are achieved by the method according to the invention for the treatment and elimination of solid, liquid or pasty waste of domestic and / or industrial origin, part of which consists of plastic waste, according to which the said said are selected. waste, by combustible or non-combustible category and the waste of each category is sent to a treatment station for recovery or destruction, characterized by the following operations
- selecting said solid, liquid and pasty waste, destructible by combustion
- said combustible solid waste is ground in order to obtain a ground material
- at the same time, part of the plastic waste is liquefied, immersing it in a solvent bath
- Said ground material is mixed with said liquefied plastics and other toxic or non-toxic liquids to be destroyed, which are kneaded and which are triturated in order to obtain a pasty composition
- A plurality of elements is produced from this pasty composition, of generally cylindrical or tubular shape, or spherical, or ovoid, or annular, or in the form of a pellet
- said elements are dried by heating them to obtain a fuel coated in plastic material and which can be stored or handled mechanically
- And this fuel is destroyed by burning it in a closed cup at high temperature, with the addition of atmospheric air or pure oxygen.

More particularly, said liquid or pasty solid waste, which can be destroyed by combustion, is selected.
- said waste is weighed continuously on arrival and the values from said weighing are entered into the memory of a central computing unit
- The grinding of said combustible solid waste is carried out with a view to obtaining a ground material with a particle size passing through the mesh of between 0.01 and 6 millimeters
- at the same time, the plastic waste of the polyvinyl chloride, polyethylene, polystyrene or other type is liquefied by immersing it in a solvent bath
- Introducing said ground material. said liquefied plastics and other toxic and non-toxic liquids to be destroyed, in a mixer-pulverizer according to weight percentages given by said central computing unit and said ground materials and said liquids are kneaded and triturated. with a view to obtaining a pasty composition
- This pasty composition is sent under pressure through an extruder-cutter, in order to obtain a plurality of elements
- Said elements are dried and hardened by heating them to obtain said fuel.

To grind solid waste, we operate as follows
- a first grinding is carried out at a particle size passing to the mesh between 0.01 and 25 millimeters
- a first transformation of this ground material is carried out by adding to it powder of so-called hard plastic waste, at a rate of 0.8% to 3.5% by weight and this ground material added with this powder is transferred to a crystallization and at the outlet of said oven, a second grinding of said crystallized ground material is carried out, in order to reduce it to a particle size passing to the mesh between 0.01 and 6 millimeters.

 Said toxic and non-toxic liquids are introduced into the mixer-pulverizer in order to associate them with said ground material and with the liquefied plastic material.

 For the elimination of waste oils, there is incorporated into the ground material and the liquefied plastic material a weight value of such oils of between 5 and 20%, depending on the absorption capacity of the ground material.

 For the elimination of toxic or non-toxic liquids other than waste oils, it is incorporated into the ground material and the plastic material. liquefied a value by weight of non-toxic or toxic liquids of between 2.5 and 5%.

 In order to accelerate the curing of the fuel, a hardener of the synthetic resin type is incorporated into said pasty composition, at a rate of 3% to 8%.

 To amalgamate the waste together and isolate it from the outside environment in a protective envelope, the said plastic materials are liquefied by immersing them in acetone or the like.

 For the manufacture of said fuel, between 35 and 90% by weight of household and / or industrial waste and / or household waste is used and between 10 and 23% by weight of liquefied plastics are incorporated therein.

 According to the process and, with the aim of discharging low-polluting gases into the atmosphere, the fuel is then destroyed by pyrolysis and the gases resulting from the pyrolysis by combustion in a closed vessel and at high temperature, with the addition of atmospheric air or over-oxygenated.

 For more effective protection of the environment, said fuel is destroyed by pyrolysis and the gases resulting from pyrolysis by combustion in a closed vessel and at high temperature with the addition of pure oxygen, in order to minimize the nitrogen oxides produced by fuel components.

 According to said method, said fuel is destroyed in a furnace by pyrolysis and the pyrolysis gas is destroyed by combustion in a boiler, to produce usable energy. To do this, the pyrolysis gases are captured at the outlet of said oven and these gases are destroyed in said boiler by means of at least one burner on which the flow of atmospheric air or pure oxygen is continuously adapted oxidant, as a function of the flow rate and of the composition of the gases, in order to obtain stoichiometric combustion, in particular by combustion with pure oxygen.

 For the implementation of the continuous and automatic process, the pyrolysis gas flow is captured and samples of this gas are taken, the information collected is sent to an electronic analyzer associated with a programmable controller and comprising a memory in which are stored the parameters relating to the nature of the components of the gas and of the flows of gas and of combustion air or of pure oxygen, which analyzer compares the data taken from the emission of gases with said parameters and manages, through said automaton and a remote control, the flow of combustion air or pure oxygen supplied to said burner, in order to achieve stoichiometric combustion.

 According to the process, the pyrolysis gas is destroyed with the addition of atmospheric or oxygenated air, by raising the combustion temperature between 1300 K and 2000 K.

 In another mode of application of the process, the pyrolysis gas is destroyed with the addition of pure oxygen, by raising the combustion temperature between 2500 K and 2600 K.

 The gases produced by the transformation of the waste are possibly captured, these gases are mixed with the pyrolysis gases and the resulting gases are destroyed by combustion.

 These objectives are also achieved by the fuel according to the invention, allowing in particular the implementation of the process, which fuel is characterized by the fact that it consists of solid and liquid or pasty household and / or industrial waste, of which said waste solids reduced to a ground product and mixed with said liquid and / or pasty waste, are agglomerated and linked together by a plastic binder which, in addition, coats the fuel.

 According to the invention, said plastic binder is plastic material of polyvinyl chloride, polyethylene, polystyrene or other type derived from said waste.

 Said fuel can take any general cylindrical, or spherical, or ovoid, or annular, or tubular, shape or that of a pellet. Preferably, it takes the form of a cylindrical tube, the central duct of which establishes a circulation of gases and of oxidant inside the fuel, to increase its speed of destruction by regular and rapid combustion of the pyrolysis.

 According to one embodiment, it comprises between 35 and 90% by weight of household and / or industrial waste and / or household waste and between 10 and 23% by weight of plastic material of polyvinyl chloride, polyethylene, polystyrene type or similar.

 It also comprises a hardener of the synthetic resin type at a rate of 3% to 8% by weight.

 For the elimination of non-toxic or toxic liquid waste comprising or not draining oils, the fuel comprises between 2 and 5% by weight of non-toxic or toxic liquids, other than draining oils.

 For the elimination of waste oils, the fuel comprises between 5 and 20% by weight of such oils.

 In one embodiment, said fuel consists of 80 to 90% by weight of household waste, including liquid waste and said hardener and from 10 to 20% by weight of plastic materials to release a calorific energy of the order from 13.5 to 16.5 MJ per kilogram.

 In another embodiment, it consists of 75% by weight of household waste including liquid waste and hardener, 20% by weight of plastic materials and 5% by weight of cardboard waste to release heat energy. around 17 MJ per kilogram.

 In another embodiment, it is composed of 70% by weight of household waste including liquid waste and said hardener, 20% by weight of plastic materials and 10% by weight of paper waste to release heat energy around 18 MJ per kilogram.

 In yet another embodiment, it consists of 65% by weight of household waste, including liquid waste and said hardener, 20% by weight of plastics, 10% by weight of paper waste and 5 % by weight of wood waste to release a heat energy of the order of 18.5 MJ per kilogram.

 In another exemplary embodiment, it consists of 60% by weight of household waste, including liquid waste and said hardener, of 20% by weight of plastics, of 5% by weight of tire waste, of 4% by weight of wood waste, 1% by weight of textile waste and 10% by weight of cardboard waste to release a heat energy of 20 MJ per kilogram.

 According to another example, it consists of 55% by weight of household waste, including liquid waste and hardener, 20% by weight of plastics, 15% by weight of cardboard waste and 10% by weight waste paper to release a heat energy of the order of 20 MJ per kilogram.

 According to yet another example, it consists of 50% by weight of household waste, including liquid waste and hardener, 20% by weight of plastics, 5% by weight of tire waste, 5% by weight. weight of wood waste, 2% by weight of textile waste, 10% by weight of paper waste, and 8% by weight of cardboard waste to release a calorific energy of the order of 21 MJ per kilogram.

 According to another example, it consists of 45% by weight of household waste, including liquid waste and hardener, 21% by weight of plastics, 15% by weight of cardboard waste, 11% by weight of paper waste, 2% by weight of wood waste, 1% by weight of tire waste, 1% by weight of textile waste and 3% by weight of dust and earth to release a calorific energy of around 21 MJ per kilogram.

 According to another example, it consists of 40% by weight of household waste, including liquid waste other than waste oil and hardener, 22% by weight of plastics, 15% by weight of cardboard waste, 12 % by weight of paper waste, 4E by weight of wood waste and 7% by weight of waste oils to release a heat energy of the order of 23.5 MJ per kilogram.

 According to another exemplary embodiment, it consists of 35% by weight of household waste, including liquid waste and hardener, 23% by weight of plastics, 20% by weight of decantation sludge, of 2% by weight tire waste, 4% by weight of wood waste, 7% by weight of waste oils and 9% by weight of cardboard waste to release heat energy of the order of 22.5 MJ per kilogram.

 The invention results in the elimination of solid and liquid, pasty or gaseous domestic and industrial waste, while respecting the environment by discharging low-polluting or almost completely depolluted gases into the atmosphere.

 The invention also results in a fuel making it possible to produce, by implementing said method and economically, an energy usable for domestic or industrial purposes.

Other advantages and characteristics of the invention will emerge further on reading the following description given by way of nonlimiting example, with reference to the appended drawings in which
- Figure 1 is a block table of an installation implementing the method according to the invention
- Figure 2 is a perspective view on a large scale, of the fuel obtained by said process and for its implementation, in its preferred form
- Figure 3 is a partial sectional view / exterior view of the fuel of Figure 2.

 According to the method, the elimination of household and industrial waste, including agricultural waste, involves the use of a fuel and the destruction of this fuel under specific conditions as set out above and which will be explained in more detail details during the description given below.

 Whatever their state, solid, liquid, pasty or gaseous, or their provenance, household, agricultural or industrial or even their nature or composition, plastic, rubber, elastomer, wood, chemicals, paper and cardboard, textile, oil emptying and other, toxic liquids or not, settling sludge, etc ..., such waste destructible by fire are likely to produce heat energy that the process according to the invention, tends to recover.

 Given the wide variety of such wastes and their origin at the place of treatment, at random, it is understood that the proportions and the nature of the components used in the manufacture of the fuel according to the invention, can vary within a very wide range measured.

 The physical and caloric qualities of the fuel therefore derive from the nature of the waste put to destruction and from the collection on the day of its arrival on the treatment site.

 Nevertheless, it is possible despite the heterogeneity of urban, agricultural or industrial residues, to establish an assessment of the average calorific value of such waste, on the basis of statistics made over a long period of two years and affecting the production of waste from 'an agglomeration of the order of 200,000 inhabitants.

 From these statistics follows the fact that the calorific value of everything coming in bulk on arrival at the treatment site and before transformation, is established between 6.3 and 14.3 MJ, this being of course depending on the qualities and varieties of waste taken into account such as plastics, paper and cardboard for example which, as we know, can be subject to recovery.

 The use of such products, as part of the process, is therefore dependent on the market for recovered raw materials and the economic value of these materials. It is obvious that if their market value is insufficient, at least part of this waste can enter the composition of the fuel by increasing its calorific value, which can thus reach around 23 MJ.

 Otherwise, it will be reduced to around 13.5 MJ, it being specified that the production of fuel involves the use of plastic waste, such as that from beverage bottles, food packaging, various pipes or other products of such materials based on polymers or copolymers of polyvinyl chloride, polyethylene, polystyrene, polyurethane or other ... these materials being capable of constituting on the one hand, a binder for the binding of waste and to form on the other hand, a protective envelope which guarantees the fuel's resistance over time to its storage and allows its handling.

 Such a fuel, the initially polluting waste of which is embedded and coated in said plastic binder and hardened in its final manufacturing phase, also offers the advantage of being completely non-polluting, its components thus being "trapped" in the plastic .

 A nonlimiting example of implementation of the method according to the invention is now set out with reference to FIG. 1 of the drawing relating to a block diagram giving the successive phases of said method: from the reception of the raw combustible waste until its destruction.

 The item referenced 1 is therefore located downstream of the reception of the waste in its initial state, where a first selection is made at the entrance to the treatment site to direct the non-combustible recyclable products, such as for example ferrous metal products and non-ferrous and certain plastics, to a recovery center and combustible waste of any kind and origin to said station 1.

 The latter receives said bulk waste in its raw state. I1 can for example be constituted by a deposit area from which the waste is conveyed in the various circuits of the treatment chain.

 The waste from station 1 is conveyed by means of, for example, a conveyor, to a sorting and weighing station 2. Weighing is carried out at this station as and when it arrives, by means of a or several electronic scales, after sorting of waste according to its nature. The diagram gives an example of the variety of sorted products referenced 2a to 21, namely: plastics of all origins 2a, paper waste 2b, cardboard waste 2c, wood and vegetable waste 2d, dust and earth 2nd, waste oils 2f, textiles 2g, rubber and tires 2h, household waste 2j, PVC or similar plastics 2k, non-toxic and toxic liquid waste other than waste oil 21.

 The values by weight of each type of waste are introduced into the memory of a central computing unit 3, which also has in memory the different parameters relating to the various possible compositions of the fuel, with a view to its manufacture. After weighing, the waste is temporarily stored. Depending on the varieties of waste and their quantity on arrival, the central unit 3 controls directly or through automata the transfer means of each variety to bring them to the various stations of the fuel production chain. The quantities of waste managed by said unit 3 are given as a percentage by weight and transformed for example in a digital to analog converter to control the flow of materials at the various stations of the chain.

 The solid waste from station 2 (2a to 2d and 2g to 2j) is conveyed to a grinding station comprising a first grinding unit 5, a crystallization oven 6 and a second grinding unit 7. Part of the so-called plastics hard, i.e. thick pieces of polyvinyl chloride, polystyrene or based on polyester resin for example, are first crushed and screened at station 4 to reduce part of these powdered materials.

The percentages by weight of said solid waste which can go into the production of one tonne of fuel are given below by way of example.
- 10% plastic waste from item 2a, i.e. 100 kgs,
- 10% of paper waste from station 2b, i.e. 100 kgs,
- 11% of cardboard waste from station 2c, i.e. 110 kgs,
- 3% wood waste from station 2d, i.e. 30 kgs,
- 1% of textile waste from item 2g, i.e. 10 kgs,
- 1% of rubber / tire waste from the 2-hour shift, i.e. 10 kgs,
- 40% of household waste from station 2d, i.e. 400 kgs.

 All this solid waste is introduced into the grinding unit 5 in order to reduce it, for example, to a particle size passing to the mesh of 25 millimeters.

 On leaving unit 5, the crushed waste undergoes a first transformation by adding plastic powder from station 4, for example at a rate of 1.5%, or 15 kg of powder.

 The ground material from unit 5 added with this powder is then passed through said crystallization oven 6, for about four minutes, at a temperature of the order of 1800C.

 At the outlet of this oven, the ground product is in the form of agglomerates of mechanical strength equivalent to that of very friable wafers.

 The ground material from the crystallization furnace 6 is then introduced into a second grinding unit 7 to reduce it, for example, to a particle size passing through the mesh of 2 millimeters.

 At the outlet of the grinding unit 7, the ground material thus reduced and the dust resulting from the grinding is sent to a mixer-pulverizer 8.

 In parallel with said operations carried out at said grinding stations 5, 6, 7, waste plastics with a thin or flexible or brittle wall, such as based on polyvinyl chloride, polyethylene or expanded polystyrene, for example bottles of drinks food, food packaging, plastic fabrics, box covers, flexible or rigid pipes and all other such waste, are transformed from their solid state to a liquid state by passing to the dissolution-liquefaction station 9.

 At this station, said waste is immersed in a bath of a solvent such as acetone 10 or the like. The liquefied plastics are then stored at station 11.

 Said liquid waste from stations 2f, 21 and 11, are sent through a network of pipes and by means of pumping units, for example volumetric, in said mixer-pulverizer 8 in proportions defined by the central computing unit 3 , using digital / analog means, similar to those used for solid waste.

So introduced into said mixer-pulverizer 8, for mixing with said solid waste
- 3% by weight of toxic liquids, such as acids diluted in other liquid waste from station 21, i.e. 30 kgs,
- 6% by weight of drain oils from station 2f, i.e. 60 kgs,
- 10% by weight of liquefied plastics from station 11, i.e. 100 kgs.

We also introduce into the mixer-pulverizer
- 2% of dust and earth from station 2e, i.e. 20 kgs, as well as 3.5% of hardener 12, i.e. 35 kgs.

 The mixing time is approximately five to six minutes.

 At the end of this kneading-crushing at station 8, the pasty composition obtained is sent under a pressure of the order of 600 bars to an extrusion-cutting unit 13 which produces, at its outlet, a plurality of pasty elements 14 , which can take any shape, in particular cylindrical, tubular, ovoid, spherical, pellet-shaped, etc.

 Preferably and for reasons which will be explained below, the cylindrical tubular embodiment has been chosen.

 Said pasty tubular elements are then conveyed by conveyor or any other means to a drying station 15 in order to obtain said combustible elements in their final constitution.

 Said station 14 comprises for example a tunnel oven in which the said elements have passed for for example five to six minutes, and in which their physical transformation from their pasty state to a solid state, takes place by thermosetting.

 On leaving said station 15, said fuels are stored in a reserve or an area 16, with a view to their destruction, the operational methods of which are explained below.

 A fuel element according to the invention 17 is shown in external view in FIG. 2 and in partial section / external view in FIG. 3. It adopts a cylindrical tubular shape, the dimensions of which can vary depending on the capacities of the destruction means. . Thus, the external diameter D can for example be between 8 and 30 millimeters, the internal diameter d of the central duct 17a, between 3 and 15 millimeters, the length 1 between 30 and 60 millimeters.

For practical reasons inherent in economic considerations affecting the pyrolysis / combustion equipment used by the process where such equipment is chosen to be of modest dimensions, the dimensions of the fuel have been fixed at
- outside diameter D, 8 to 10 millimeters,
- internal diameter d, 3 to 4 millimeters,
- length 1, about 30 millimeters.

 Its density is of the order of 0.3 to 0.6, including profusion.

 The advantages of such a fuel arising from the process according to the invention are numerous.

 On the one hand, the addition to the comminuted solid and liquid waste of plastics, part of which said material has been liquefied, makes it possible to obtain a fuel whose crushed solid waste 18 is "trapped" in this material 19. In Indeed, each particle of the ground material is coated with plastic material 18, this plurality of particles being amalgamated by means of said agglomerant 19, to form a tubular element thus comprising a protective envelope both external 19a and internal 19b, which completely isolates the particles. waste from the outside environment.

 Since such a material is deemed to be non-biodegradable, it is understandable that the conservation of such a fuel can be very long. In addition, the polluting waste being isolated in the hardened plastic, the storage of said fuel offers all the guarantees of safety for the environment.

 In addition to these ecological advantages, the fuel according to the invention makes it possible to achieve results and other advantages of a thermal order, for its use with a view to the production of an economic energy usable for domestic or industrial purposes by its destruction. Thus the central duct 17a has a specific function which makes it possible to carry out the circulation of the pyrolysis and oxidant gases at the internal and external periphery of the fuel, thereby exerting a very great influence on the speed of pyrolysis of the fuel.

 A first result which makes it possible to achieve the invention is a perfectly homogenized and self-purifying pyrolysis gas using the outer unburned peripheral fuel layer, as a purifying filter.

 A second result obtained is perfect consumption, which results in the almost total elimination of unburnt materials and a significant reduction in residual ash of the order of 10 to 15% by weight of the tonnage of fuel put to destruction and in operation the nature of the waste composing it, especially when it includes non-combustible parts.

 We again refer to the block diagram of FIG. 1.

 The fuel stored at station 16 is, according to the process, destroyed in a specific installation making it possible to produce usable energy.

 Said fuel is thus destroyed by pyrolysis in an oven 20, the supply of which can be carried out continuously or discontinuously. It is the same for the unloading of the "solid skeleton remaining after the pyrolysis.

 In this furnace, at almost ambient pressure, only the fuel according to the invention and the gases it releases are present, which are based on more or less complex molecules, themselves constructed from carbon, l hydrogen, nitrogen and oxygen, all these elements coming from the fuel itself to the exclusion of any external input.

 The remaining hot skeleton can be reduced to powder and calcined or burned by combustion in air or in oxygenated air, in order to further reduce the mass of what constitutes irreducible solid waste.

 It is interesting to note that, given their treatment, this pyrolysis waste is free from any bacteriological pollution. The ashes are removed in 20a.

 The gases from pyrolysis 21 are collected at the outlet of the oven 20 and are destroyed by combustion through one or more burners 22, in a steam or water boiler 23, depending on the energy 24 required for use that we want to make of it, such as for example the steam drive of electric turbines or the collective heating of groups of buildings or greenhouses of cultures by production of hot water and the self-supply of the installations.

 This combustion of the pyrolysis gases is carried out with the supply of atmospheric or superoxygenated air 25, or even with the supply of pure oxygen from liquid storage 26. The supply of the oxidant to the burner (s) 22 is carried out so automatic, where its flow rate is adapted in real time to the flow rate and the composition of the pyrolysis gases in order to achieve stoichiometric combustion.

 It will be seen later that the use of pure oxygen as an oxidizer for this combustion makes it possible, thanks to the invention, to discharge gases and fumes that are practically decontaminated, moreover the volume of the fumes is three to four times lower than that resulting from combustion with ordinary air.

 By way of example and, in view of these advantages, the characteristics of the means used by the process for the destruction of pyrolysis gases with the addition of pure oxygen are therefore set out below.

 To supply the oxidant to the burner (s) 22 automatically, as mentioned above, the flow of pyrolysis gases 21 from the oven 20 is continuously captured, for example, and samples of this gas which are sent to an electronic analyzer 27, associated with a programmable automaton 28. Said analyzer 27 comprises a memory in which the parameters relating to the nature of the gas components and of the gas and flow rates are stored oxidizing oxygen, which analyzer compares the data taken from the emission of gases with said parameters and manages, through said automaton 28 and a remote control 29, said pure oxygen supplied to the burner (s) 22.

 According to the process used, the temperature of the gases is significantly higher than in the case of combustion in air, since there is no longer needlessly heating an enormous mass of nitrogen of the order of four fifths of the total mass of smoke.

 Thus, according to the invention, the combustion temperature of the pyrolysis gases is raised to approximately 2500 K, this temperature however being able to be between 2500 K and 2600 K.

All the combustion gases are, under these conditions, active in the infrared and radiate towards the walls. The thermal surface flux circulating towards the walls, such as those of the pyrolysis furnace 20 or the water or steam tubes of the boiler 23 is considerably increased by the following three processes
- increase in radiation due to the rise in temperature
- increase in radiation regardless of the above cause by the increase in the emission factor of gases, all active in the infrared while nitrogen is not
- increased convection.

 A substantial reduction in the size of the heaters, and therefore in the cost of the assembly, results from this design.

 In addition, it is possible, but to a lesser extent than that of the two radiation effects mentioned above, to expect an increase in convection. In this regard, these are complex effects.

 The reduction in the size of the devices decreases the area of convective exchange with hot gases. Furthermore, these are in less mass (no nitrogen) as set out below. However, the reduction in the cross section of the gas passages increases their speed, as does the average temperature difference between the fumes and the walls.

 A global assessment of these different aspects shows a convective gain compared to combustion in air.

 The smoke volume is reduced in a ratio of the order of three, compared to that of conventional installations, with all the splendid consequences described above and relating to the economic production of energy and the protection of 1 ' environment..

 Also the high thermal level of the oven allows a Carnot yield comparable, for an installation producing steam, to that of the best thermal power plants, and therefore an electricity production with an excellent yield of all the energy self-consumed by the installation.

 This electricity can moreover be produced preferentially during peak hours of consumption.

 Finally, the method according to the invention makes it possible to provide a solution to gaseous pollution favorable to the environment, by the rejection to the atmosphere of fumes which are very largely decontaminated.

 The advantage of the process has already been explained above with regard to the reduction of solid waste resulting from pyrolysis which can still be optionally reduced to powdery ash by combustion with oxygen and to the substantial reduction in the mass of smoke.

 We know that the two most harmful gaseous pollutants are CO and NOx.

 With regard to CO, its disappearance with the rise in temperature is conventional and known.

 On the other hand, the increase in the thermal level is rather considered as being favorable to the creation of nitrogen oxides.

Thus, the nitrogen in the air, that is to say from N2, must be dissociated into N and N at very high thermal levels, for example at characteristic temperatures of the order of 2500 K, these N and N atoms then combine with the oxygen in the air to give nitrogen oxides. On the other hand, the dissociation of the bound nitrogen in the waste, is already completely obtained at temperatures of the order of 1500 K that ordinary combustions in air achieve, according to the following process
N linked to waste B CN and HCN -, NOx
T "1500 K in the presence of 02.

 In this process, combustion with oxygen, even at high temperature, produces no more nitrogen oxide from the waste than does combustion with ordinary air.

 On the other hand, nitrogen oxide, the initial nitrogen of which comes from the combustion air in the conventional process, is not produced since, by definition, the oxidizer is pure oxygen.

In summary, and concerning the essential question of gas pollution, 9n notes that raising the temperature to 2500 K with pure oxygen instead of 1500 K with combustion air, has the effect
- to completely eliminate the formation of CO,
- not to produce the nitrogen oxides produced by combustion in atmospheric air,
- not to produce more nitrogen oxide from the waste than ordinary combustion produces.

 On the contrary, it is possible to envisage a partial purging of the nitrogen from the pyrolysis gases before their use as a fuel in the oxidizing oxygen burner (s).

 The counterpart of the rejection to the atmosphere of gases practically decontaminated, however implies the use of a tonnage of liquid oxygen 26 equal to 1.5 or 2 times the tonnage of solid fuel obtained by the process.

 In addition to the pyrolysis gases, the gases from the installation, for example from the liquefaction of plastics at stations 9/11, from the mixing of waste at station 8, can also be destroyed under the conditions just exposed. gases emitted by liquids passing through stations 2f / 21, as well as residues of CFC type gases from aerosol cans and other gases produced by the treatment installation.

 All these gases are stored in a reserve 30 and are sent according to doses defined by the central computing unit 3, for example through volumetric valves, at the outlet of the oven 20, and are mixed with the pyrolysis gases from said oven to be destroyed by combustion.

 Of course, without departing from the scope of the invention, the parts which have just been described by way of example, may be replaced by a person skilled in the art by equivalent parts fulfilling the same function.

Claims (37)

CLAIMS.  1. Process for the treatment and elimination of solid, liquid or pasty waste of domestic and / or industrial origin, part of which consists of plastic waste according to which said waste is selected, by fuel category (1) or non-combustible and the waste of each category is sent to a treatment station for recovery or destruction, characterized by the following operations  - selecting said solid, liquid and pasty waste, destructible by combustion (1)  - said combustible solid waste (5/7) is ground, in order to obtain a ground material  - in parallel, a part (2k) of the plastic waste is liquefied, by immersing it in a solvent bath (10);  - The ground material is mixed with said liquefied plastics (11) and other toxic or non-toxic liquids (2f / 21) to be destroyed, which is kneaded (8) and which is triturated in order to obtain a pasty composition  - A plurality of elements (14), generally cylindrical or tubular, or spherical, or ovoid, or annular, or in the form of a pellet, are produced from this pasty composition  - drying by heating (15) said elements (14) to obtain a fuel coated in plastic (17), and which can be stored or handled mechanically  - And this fuel (16) is destroyed by burning it in a closed vessel (20/23) at high temperature, with the addition of atmospheric air (25) or pure oxygen (26).  2. Method according to claim 1, characterized by the following operations  - selecting said liquid or pasty solid waste, destructible by combustion (1)  - said waste is continuously weighed on arrival (2a-21) and the values from said weighing are entered into the memory of a central computing unit (3)  - The grinding of said combustible solid waste is carried out (2a to 2d / 2g to 2d) with a view to obtaining a ground material with a particle size passing to the mesh of between 0.01 and 6 millimeters  - at the same time, the plastic waste of polyvinyl chloride, polyethylene, polystyrene or other type (2k) is liquefied, by immersing it in a solvent bath (9/10)  said ground material, said liquefied plastics (11) and other toxic and non-toxic liquids (2f / 21) to be destroyed are introduced into a mixer-pulverizer (8), according to weight percentages given by said central computing unit ( 3) and kneaded and triturated said ground materials and said liquids, in order to obtain a pasty composition  - This pasty composition is sent under pressure through an extruder-cutter (13), in order to obtain a plurality of elements (14)  - Said elements (14) are dried and hardened by heating them (15), to obtain said fuel (17).  3. Method according to any one of claims 1 or 2, characterized in that, to grind the solid waste (2a to 2d / 2g to 2d), the procedure is as follows  - A first grinding (5) is carried out at a particle size passing to the mesh between 0.01 and 25 millimeters;  - a first transformation of this ground material is carried out by adding to it powder of so-called hard plastic waste (4), at a rate of 0.8% to 3.5% by weight and this ground material added with this powder is transferred into a crystallization oven (6)  - And, at the outlet of said furnace (6), a second grinding (7) of said crystallized ground material is carried out, in order to reduce it to a particle size passing to the mesh between 0.1 and 6 millimeters.  4. Method according to any one of claims 1 to 3, characterized in that one introduces into the mixer-pulverizer (8) said toxic and non-toxic liquids (2f / 21) to associate them with said ground material and the material liquefied plastic (11).  5. Method according to claim 4, in which the toxic liquids are waste oils (2f) characterized in that a ground value of waste oil (2f) is incorporated into the comminuted product and the liquefied plastic material (11) between 5 and 20%.  6. Method according to claim 4, the toxic liquids of which may or may not contain drain oils, characterized in that a ground value of non-toxic or toxic liquids (21) is incorporated into the ground material and the liquefied plastic material (11). ) other than drain oils (2f), between 2 and 5%.  7. Method according to any one of claims 1 to 6, characterized in that a hardener (12) of synthetic resin type is incorporated in said pasty composition at a rate of 3% to 8%.  8. Method according to any one of claims 1 or 2, characterized in that liquefies said plastic materials (2k) by immersing them in acetone or the like (10).  9. Method according to any one of claims 1 to 8, characterized in that, for the manufacture of said fuel (17), between 35 and 90% by weight of household and / or industrial waste and / or garbage is used. housewives.  10. Method according to any one of claims 1 to 9, characterized in that for the manufacture of said fuel, there is incorporated between 10 and 23% by weight of liquefied plastics.  11. Method according to any one of claims i to 10, characterized in that said fuel (17) is destroyed by pyrolysis (20) and the gases resulting from pyrolysis (21) by combustion in a closed vessel and at high temperature. , with atmospheric (25) or superoxygenated air supply.  12. Method according to any one of claims 1 to 10, characterized in that said fuel (17) is destroyed by pyrolysis (20) and the gases resulting from pyrolysis (21) by combustion in a closed vessel and at high temperature with supply of pure oxygen (26), in order to limit as much as possible the nitrogen oxides produced by the fuel components (17).  13. Method according to any one of claims 2 and 11 or 12, characterized in that said fuel (17) is destroyed in an oven (20) by pyrolysis and that the pyrolysis gases (21) are destroyed. by combustion in a boiler (23), to produce usable energy (24).  14. Method according to claim 13, characterized in that the pyrolysis gases (21) are captured at the outlet of said oven (20) and that these gases are destroyed in said boiler (23) by means of minus one burner (22) on which the flow of atmospheric air (25) or of oxidizing pure oxygen (26) is continuously adjusted, as a function of the flow and composition of the gases (21), in order to obtain the toechiometric combustion.  15. Method according to claim 14, characterized in that continuously, the flow of pyrolysis gas (21) is captured and samples of this gas are taken, in that the information collected is sent to an electronic analyzer ( 27) associated with a programmable automaton (28) and comprising a memory in which the parameters relating to the nature of the components of the gas (21) and of the gas flows (21) and of the combustion air (25) or of are stored pure oxygen (26), which analyzer (27) compares the data taken from the emission of gases (21) with said parameters and manages, through said automaton (28) and a remote control (29), the flow of combustion air ( 25) or pure oxygen (26) supplied to said burner (22), in order to achieve tooichiometric combustion.  16. Method according to any one of claims 2 and 11 to 15, characterized in that the pyrolysis gas (21) is destroyed with the addition of atmospheric air (25) or oxygenated by raising the combustion temperature between 1300 K and 2000 K.  17. Method according to any one of claims 2 and 11 to 15, characterized in that the pyrolysis gas (21) is destroyed with the supply of pure oxygen (26), by raising the combustion temperature between 2500 K and 2600 K.  18. Method according to any one of claims 1 to 17, characterized in that the gases (30) produced by the transformation of the waste are captured, these gases (30) are mixed with the pyrolysis gases (21) and destroys the resulting gas by combustion.  19. Fuel (17) characterized in that it consists of solid, liquid or pasty household and / or industrial waste (2a to 21), of which said solid waste reduced to a ground material (18) and mixed with said liquid waste and / or pasty, are agglomerated and bonded together by a plastic agglomerator (19) which, in addition, coats the fuel.  20. Fuel according to claim 19, characterized in that said plastic binder (19) is plastic material of polyvinyl chloride, polyethylene, polystyrene or other type (2k) from said waste.  21. Fuel (17) according to any one of claims 19 and 20, characterized in that it adopts a generally cylindrical, or spherical, or ovoid, or annular, or tubular, or that of a pellet and is d '' a density between 0.3 and 0.6.  22. Fuel according to any one of claims 19 and 20, characterized in that it takes the form of a cylindrical tube (17), the central duct (17a) establishes a circulation of gases and oxidant to the inside the fuel, to increase its speed of destruction by regular and rapid combustion of the pyrolysis.  23. Fuel (17) according to any one of claims 19 to 22, characterized in that it comprises between 35 and 90% by weight of household and / or industrial waste and / or household waste (2d).  24 Fuel (17) according to any one of claims 19 to 23, characterized in that it comprises between 10 and 23% by weight of plastic material (2k) of polyvinyl chloride, polyethylene, polystyrene or similar type.  25. Fuel (17) according to any one of claims 19 to 24, characterized in that it comprises a hardener (12) of synthetic resin type at a rate of 3% to 8% by weight.  26. Fuel (17) according to any one of claims 19 to 25, part of the household and / or industrial waste is non-toxic or toxic liquid waste (21) comprising or not drain oil (2f), characterized in that it comprises between 2 and 5% by weight of non-toxic or toxic liquids (21), other than drain oils (2f).  27. Fuel according to any one of claims 19 to 26, the toxic liquids of which are waste oils (2f), characterized in that it comprises between 5 and 20% by weight of such oils.  28. Fuel according to any one of claims 19 to 27, characterized in that it consists of 80 to 90% by weight of household waste, including liquid waste (21) and said hardener (12) and of 10 at 20% by weight of plastics (2k) and giving off a calorific energy of the order of 13.5 to 16.5 MJ per kilogram.  29. Fuel according to any one of claims 19 to 27, characterized in that it consists of 75% by weight of household waste (2k) including liquid waste (21) and said hardener (12), of 20 % by weight of plastic materials (2k) and 5% by weight of cardboard waste (2c) and releasing a calorific energy of the order of 17 MJ per kilogram.  30. Fuel according to any one of claims 19 to 27, characterized in that it consists of 70% by weight of household waste (2d) including liquid waste (21) and said hardener (12), of 20 % by weight of plastic materials (2k) and 10% by weight of paper waste (2b) and releasing a calorific energy of the order of 18 MJ per kilogram.  31. Fuel according to any one of claims 19 to 27, characterized in that it consists of 65% by weight of household waste (2d), including liquid waste (21) and said hardener (12), 20% by weight of plastic materials (2k), 10% by weight of paper waste (2b) and 5% by weight of wood waste (2d) and releasing a calorific energy of the order of 18.5 MJ per kilogram.  32. Fuel according to any one of claims 19 to 27, characterized in that it consists of 60% by weight of household waste (2d), including liquid waste (21) and said hardener (12), 20% by weight of plastics (2k), 5% by weight of tire waste (2h), 4% by weight of wood waste (2d), 1% by weight of textile waste (2g) and 10% by weight of cardboard waste (2c) and releasing a heat energy of 20 MJ per kilogram.  33. Fuel according to any one of claims 19 to 27, characterized in that it consists of 55% by weight of household waste (2d), including liquid waste (21) and the hardener (12), 20% by weight of plastics (2k), 15% by weight of cardboard waste (2c) and 10% by weight of paper waste (2b) and releasing a calorific energy of the order of 20 MJ per kilogram .  34. Fuel according to any one of claims 19 to 27, characterized in that it consists of 50% by weight of household waste (2d), including liquid waste (21) and the hardener (12), 20% by weight of plastics (2k), 5% by weight of tire waste (2h), 5% by weight of wood waste (2d), 2% by weight of textile waste (2g), 10% by weight of paper waste (2b), and 8% by weight of cardboard waste (2c) and releasing a heat energy of the order of 21 MJ per kilogram.  35. Fuel according to any one of claims 19 to 27, characterized in that it consists of 45% by weight of household waste (2d), including liquid waste (21) and the hardener (12), 21% by weight of plastic materials (2k), 15% by weight of cardboard waste (2c), 11% by weight of paper waste (2b), 2% by weight of wood waste (2d), 1% by weight of tire waste (2h), 1% by weight of textile waste (2g) and 3% by weight of earth dust (2e) and releasing a calorific energy of the order of 21 MJ per kilogram.  36. Fuel according to any one of claims 19 to 27, characterized in that it consists of 40% by weight of household waste (2d), including liquid waste (21) other than waste oils and hardener (12), 22% by weight of plastics (2k), 15% by weight of cardboard waste (2c), 12% by weight of paper waste (2b), by 4% by weight of wood waste ( 2d) and 7% by weight of waste oils (2f) releasing a calorific energy of the order of 23.5 MJ per kilogram.  37. Fuel according to any one of claims 19 to 27, characterized in that it consists of 35% by weight of household waste (2d), including liquid waste (21) and the hardener (12), 23 % by weight of plastics (2k), 20% by weight of settling sludge (21) and 2% by weight of tire waste (2h), 4% by weight of wood waste (2d), from 7 % by weight of waste oils (2f) and 9% by weight of cardboard waste (2c) releasing a calorific energy of the order of 22.5 MJ per kilogram.