BR102019027566A2 - simultaneous deaggregator and waste dryer - Google Patents

Abstract

"Simultaneous WASTE DISAGGER AND DRYER" refers to improvements introduced in a simultaneous waste separator and dryer, applied to solid, suspended and pasty solid waste in general with the purpose of eliminating environmental liabilities with the purpose of disaggregating and simultaneously dry waste or by-products for reuse, with a solids feed set (CAR), solids deaggregator set (CDS), air heating set (CA), set of dry aggregate products ducts with air and steam (DP ), gaseous effluent treatment set (TE), solid conveyor set (TS) and dry disaggregated solid products separation set from air and steam (SPA) and with advantages of reduced maintenance cost, reduced operating cost , compact and mobile installation, greater thermal efficiency, less investment in equipment and energy loss, process simplicity, better product quality. uto and higher drying efficiency.

Description

DRYER AND SIMULTANEOUS WASTE DRYER

[01] This patent refers to improvements introduced in simultaneous deaggregator and waste dryer, applied to solid, suspended liquid and pasty waste in general industrial, forestry, agricultural and urban, and with the purpose of eliminating environmental liabilities with the objective of eliminating to simultaneously disaggregate and dry leftovers or residues or by-products for reuse as fuel or as an additive to fertilizers or as animal feed, through optimized mechanical construction that obtains improvements in disaggregation, shredding, fractionation, crushing and drying of residues and with the advantages of reduction maintenance cost, reduced operating cost, compact and mobile installation, greater thermal efficiency, less investment in equipment, less energy loss, process simplicity, better quality of the final product, greater drying efficiency and repeatability of the operation.

[02] As is known by the technical means linked to the waste treatment machinery and equipment industry, currently the disposal of waste occurs through the sanitary landfill without reuse and the material drying process is carried out in the open air.

[03] In the case of forest residues, the current disaggregators are as follows:

[04] A- Knife crusher which is a system that simply reduces the length;

[05] B- Hammer crusher, which is a system that crushes the product through hammer blows and reduces its particle size;

[06] C- Chipper crusher which is a system that generates chips; and

[07] D- Fractionator of currents positioned horizontally with the solid to be fractionated fed from above and that the currents at high speed hit randomly against the material, fractionating into pieces, reducing its size.

[08] The drying of residues is currently done in complementary equipment, such as:

[09] 1. Rotary Drum Dryers that dry the material with concurrent hot air or gas in a discontinuous or continuous manner;

[10] 2. Conveyor or endless screw dryers that dry material with hot air or gas or concurrent microwaves in a discontinuous or continuous manner; and

[11] 3. Fluidized bed dryers that dry material with concurrent hot air or gas in batches or continuous.

[12] Recently the holder of this patent requested patent BR 10 2014 030988 8 which discloses a simultaneous solids deaggregator and dryer with thermal generator set, air heating set, solids deaggregator set, dry disaggregated products duct set with air and steam, separation set for dry disaggregated solid products from air and steam, solid conveyor set and gaseous effluent treatment set.

[13] Although it has obtained good practical results in the elimination of environmental liabilities, research continued to increase the efficiency and productivity of the disaggregation and drying process and obtained the improvements revealed in this patent.

[14] Searching the Brazilian and international patent database, we found the following revelations:

[15] Brazilian patent BR102012018297- system for recycling organic waste. Patent of Invention of a system for recycling organic waste comprising a supply funnel installed at the base of the cannon, thus causing the material to be directed to the screw, which will transport the material through the cannon where the drying process will take place, where all excess liquids will be captured through drains, which are filtered, thus avoiding any type of pollution resulting from the process; with the material already dry, the grinding process will take place, arriving at a product ready for consumption, thus being able to achieve a more noble and suitable destination for such organic waste, which is approximately 60% of all waste generated by households, catering companies, fairs free, supply centers and markets in general, the organic waste recycling system can be used in recycling cooperatives, garbage collection companies, city halls and any sector involved with the problem of garbage, considering that organic waste becomes an obstacle due to its incorrect disposal along with other materials such as paper, glass and plastics in general, making its recycling much more difficult, thus causing the generation of huge volumes of unusable material, that is, there are expenses with collection, transport and handling of this material, so that then, after all the aforementioned cost, 60% are disposed of in landfills, thus, the organic waste recycling system 1 makes up for the lack of machines for this purpose, making it possible to recycle all types of organic waste.

[16] U.S. Patent No. 8,714,467, which discloses a crusher/dryer having a plurality of beater blades realized on an axis of rotation in a cylindrical box, including one or a plurality of grinding members in the cylindrical side wall. The grinding members are adjustably positioned at different locations inside the cylinder. Mill members can be provided in a variety of different combinations of raised ledges and/or valleys used to dry and classify materials.

[17] US Patent No. 8,266,822, which discloses an improvement for drying sugarcane bagasse or other bagasse from briquetting or other processes includes a drying unit with a dosing of wet bagasse, hopper, which has a screw conveyor that feeds inclined screw and a rotary metering valve, the latter discharging into a hot air funnel into the drying tank, the bagasse to be lifted and exposed to hot air in the front chamber and in the final drying chamber by falling blades, through the action of the reducer motor, the almost dry bagasse in suspension being sucked out by a pair of centrifugal fans releasing them in the separator filter and falling into the hopper, being cooled in screw-open chute conveyors, screw conveyor, including the screen for the Powder separation to be conveyed by screw conveyor from inclined screw conveyor for discharge to feed hoppers to which eimators.

[18] Japanese Patent JP2000000555 Apparatus for Drying Solid Waste such as Food Waste. Problem to be solved: to dry food waste such as rice scraps to a non-wasteful degree in order to adjust it to a feedstock. Solution: Solid waste such as food waste is loaded into the loading chamber inside a main box body to be crushed by a crusher so that it is easily pre-dried and the soil waste to be treated is introduced into a chamber drying by opening an on-off shutter and the object to be treated and dried is agitated by an agitator, while the drying air generated by a drying air generator is circulated and after the moisture of the treated article is reduced to a predetermined proportion or less, this article is stored in the treated article storage chamber to be subjected to a batch treatment; by this constitution, junk food can be quickly ground and dried, without generating spoilage during preservation to form a treated material suitable for a food stock material.

[19] Canadian Patent CA 2810104, which discloses a Conditioned Biomass System and Method, the system comprises a loop and air flow chamber, the lower chamber comprises an adapter to receive biomass and elements that make up the milling, cutting and grinding elements. air inlet, an air flow from the air inlet and rotation of the elements creating an assembly composed of an inner chamber generally inside and centered on the outer chamber, the outer chamber comprising a first outlet and the inner chamber comprising a second outlet and a flange that selectively connects the lower portion, with the inner chamber and the lower portion, with the outer chamber and the air flow circuit comprising a source of inlet air at the lower part, a first discharge outlet connected to the first and to evacuate biomass and air particles from the inner chamber, and a second discharge outlet connected to the second and to evacuate steam from the air and outer chamber. Everything that deviates in the flange, from the elevator vortex and under the action of a vacuum created between the air inlet and the second outlet, a flow of water particles to the first outlet of the outer chamber and a flow of biomass particles in towards the inner chamber will be the particulate biomass that has been propelled from the inner chamber of the second outlet.

[20] Brazilian patent PI 0309699-8 "Process and apparatus for the treatment of municipal solid waste" which discloses an apparatus and process for the separation, recovery and recycling of municipal solid waste (MSW), in which hot water is added to the shredded and homogenized MSW as it enters a rotating feed preparation drum equipped with internal lifter blades. The blades and drum rotation cause mixing and pulping of the MSW, prior to discharge to a rotary thermal processor, also equipped with elevator blades and a cone section, and in which the wetted MSW is heated by heating gases hot in the processor by a flame from a burner, which converts the moisture in the MSW to steam. Steam permeates through the MSW as it is turned over and lifted in the thermal processor, causing additional pulping. The now cooked and treated MSW is then fed to a conveyor 68 for transport to a drum screen for separation of recyclable components. In one mode MSW plugs are maintained at the output and input to the thermal processor and act to provide a seal for maintaining temperature control in the thermal processor by reducing the egress of steam from there.

[21] US Patent 9,061,289 "Mechanized Separation and Recovery System for Solid Waste" which discloses methods and systems for separating a mixed waste into a wet organic fraction, a dry organic fraction and an inorganic fraction are achieved by grinding the mixed solid waste, fractionating stream crushed by size to produce two or more particles to process one or more particle-sized waste streams using density separation to produce an intermediate waste stream and recover a homogeneous product (eg, a recyclable material or an organic fuel) of the intermediate waste stream.

[22] US patent 4,298,350 "Waste conversion method" which discloses a method of converting the solid organic fraction of solid waste into a powdered fuel that comprises heating said solid organic fraction in an inert atmosphere for a time and at a time. sufficient temperature to envelop said solid organic fraction without causing substantial decomposition, pyrolysis or loss of dry weight of said solid organic fraction, grinding said embrittled solid organic fraction to a powder that is less than a predetermined particle size and recovering said powder . The inert atmosphere will comprise less than 1% by weight of oxygen and is preferably a mixture of oxides of carbon and nitrogen. The embrittlement process takes place at a temperature of at least 125 degrees. C., preferably 150 degrees. C. at 250 degrees. C. and said embrittled solid organic fraction is preferably ground to a predetermined particle size of less than 10 meshes.

[23] The disadvantages, drawbacks and limitations of current solutions are:

[24] a) Complexity of equipment;

[25] b) Lower thermal efficiency;

[26] c) Greater investment in equipment;

[27] d) Greater energy loss;

[28] e) Fixed production capacity;

[29] f) Process complexity;

[30] g) Lower quality of the final product;

[31] h) Lower drying efficiency; and

[32] i) Lack of repeatability of the operation.

[33] "Simultaneous WASTE DEBLAGER AND DRYER" object of this patent was developed to overcome the limitations, inconveniences and disadvantages of current deaggregators and dryers, because through innovative mechanical construction that allows the optimization of processes by reducing equipment , change in the heating energy source, better contact between hot air and the product and introduction of process controls, bringing advantages of reduced maintenance cost, reduced operating cost, greater thermal efficiency, less investment in equipment, compact installation and itinerant, less energy loss, process simplicity, flexibility in production capacity, better quality of the final product, greater drying efficiency and repeatability of the operation.

[34] The technical problems that the above do not solve and how it was solved by the simultaneous deaggregator and dryer of the present patent are as follows:

[35] A. Quantity and complexity of equipment, resolved by this patent through the application of electrical resistance for heating that guarantees constructive simplicity to the equipment;

[36] B. Fixed production quantity, resolved by the present patent by increasing the width of the ferrule of the solids disintegrator assembly and the disaggregated product output nozzles with air and steam, allowing the expansion of the number of streams operating inside the chamber and consequently increasing the quantity of production;

[37] C. Fixed production quantity, resolved by the present patent through the introduction of a frequency inverter driving the breaker motor and consequently increasing the production quantity;

[38] D. Heat loss due to constructive complexity, resolved by the present patent through the application of electrical resistance for heating both the air and the deaggregator, which guarantees constructive simplicity to the equipment and exposes a smaller heat dissipation area;

[39] E. Not to process suspensions of solid residues in liquids, solved by the present patent through the application of a residue feeding pump in the form of suspension that allows the introduction of the suspension directly inside the chamber;

[40] F. Low heat exchange rate of the hot air with the residue to be dried, with consequent lower drying efficiency, resolved through the introduction of baffles in the output ducts of the solids separator assembly.

[41] G. Non-guarantee of final product quality, resolved by this patent through the application of process controls that ensure the monitoring and control of temperature, humidity, rotation and flow parameters; and

[42] H. Low process productivity, resolved by the present patent through optimization by applying process controls that ensure the monitoring and control of temperature, humidity, rotation and flow parameters.

[43] In summary, the novelties that the present invention brought are: simultaneous disaggregation and drying of products using electrical resistance or electrical thermal inductor to heat the air and the deaggregator carcass, which is a novelty in relation to the previous application BR 10 2014 030988 8 by the same inventor who uses thermal oil for heating; compact set that allows transport in conventional containers and in the form of skid on wheels for itinerant use; reduction to only one module with fan and air heating radiator and with only one solid waste dosing screw; introduction of false chain link to facilitate the exchange of chain links damaged during maintenance; introduction of baffles or obstacles inside the pipes for conducting disaggregated material, hot air and steam, making better contact and consequently greater thermal exchange; feeding pump for suspensions of solid residues in liquids expanding the list of possible residues from treatment and process control with the installation of instruments for sensing and controlling temperatures, humidity, level and flow and an intelligent controller.

[44] For a better understanding of the present invention, the following drawings are attached:

[45] FIGURE 1., which shows the perspective view of the disaggregator and dryer set object of this patent in the use of solid waste.

[46] FIGURE 2., which shows the perspective view of the solid waste feeder assembly of the deaggregator and dryer object of this patent.

[47] FIGURE 3., which shows the front view of the solid waste feeder assembly of the deaggregator and dryer object of this patent.

[48] FIGURE 4., which shows the rear view of the solid waste feeder assembly of the deaggregator and dryer object of this patent.

[49] FIGURE 5., which shows the left side view of the solid waste feeder assembly of the deaggregator and dryer object of this patent.

[50] FIGURE 6., which shows details in perspective view of the conveyor screw of the solid waste feeder assembly of the deaggregator and dryer object of this patent.

[51] FIGURE 7., which shows the perspective view of the disaggregator and dryer set with alternative waste feeding set for suspended or pasty liquids, object of this patent.

[52] FIGURE 8., which shows the perspective view of the alternative waste feeding set for suspended or pasty liquids, object of this patent.

[53] FIGURE 9., which shows the front view of the alternative waste feed assembly object of this patent.

[54] FIGURE 10., which shows the rear view of the alternative waste feed assembly object of this patent.

[55] FIGURE 11., which shows the perspective view of the solid disaggregator assembly of the simultaneous disaggregator and waste dryer object of this patent.

[56] FIGURE 12., which shows the front view of the solids deaggregator assembly of the simultaneous deaggregator and waste dryer object of this patent.

[57] FIGURE 13., which shows the rear view of the solids deaggregator assembly of the simultaneous deaggregator and waste dryer object of this patent.

[58] FIGURE 14., which shows the left side view of the solids deaggregator assembly of the simultaneous deaggregator and waste dryer object of this patent.

[59] FIGURE 15., which shows the bottom view of the solids deaggregator assembly of the simultaneous deaggregator and waste dryer object of this patent.

[60] FIGURE 16., which shows the exploded view of the solids deaggregator assembly of the simultaneous deaggregator and waste dryer object of the present patent.

[61] FIGURE 17., which shows the perspective view of the chain with the detail of the false link of the breaker and dryer object of this patent.

[62] FIGURE 18., which shows the front view of the chain with the detail of the false link of the deaggregator and dryer object of this patent.

[63] FIGURE 19., which shows the perspective view of the air heating assembly for the deaggregator and dryer object of the present patent.

[64] FIGURE 20., which shows the rear view of the air heating assembly for the deaggregator and dryer object of this patent.

[65] FIGURE 21., which shows the left side view of the air heating assembly for the deaggregator and dryer object of this patent.

[66] FIGURE 22., which shows the bottom view of the air heating assembly for the deaggregator and dryer object of this patent.

[67] FIGURE 23., which shows the perspective view of the set of ducts with baffles installed in the deaggregator and dryer object of this patent.

[68] FIGURE 24., which shows the front view of the set of ducts with baffles of the deaggregator and dryer object of this patent.

[69] FIGURE 25., which shows the perspective view of the separation assembly of dry disaggregated solids products from air and steam, gaseous effluent treatment assembly and solids conveyor assembly of the deaggregator and dryer.

[70] FIGURE 26., which shows the perspective view of the separation assembly of dry disaggregated solid products from air and steam.

[71] FIGURE 27., which shows the perspective view of the gaseous effluent treatment set.

[72] FIGURE 28., which shows the perspective view of the solid conveyor assembly.

[73] FIGURE 29., which shows the block diagram of the process control of the deaggregator and dryer set of the present patent.

[74] According to the aforementioned figures, the simultaneous deaggregator and waste dryer of the present patent is constituted by a solid deaggregator set (CDS) type solids fractionator by vertical streams; Set of dry disaggregated product ducts with air and steam (DP) equipped with two metallic ducts (DP-1); Air and steam dry disaggregated solid product separation set (SPA) equipped with air and steam dry disaggregated solid product inlet (SPA-1) of hollow rectangular prismatic shape with circular tip perpendicular to the body, of cyclones (SPA -2) of hollow cylindrical shape, with a conical bottom, of product outlet valves (SPA-3) rotary or similar type, of air outlets with cyclone steam (SPA-4) of rectangular prismatic shape perpendicularly to the body; solid conveyor assembly (TS) type screw conveyor or similar connected to the product outlet valves (SPA-3) through the product inlets (TS1); A gaseous effluent treatment set (TE) equipped with air inlet ducts with steam (TE-1) of hollow rectangular prismatic shape, air inlets with steam (TE-2) of hollow rectangular prismatic shape and perpendicular to the body, of gas washers (TE-3) of the retention or chemical type and chimney (TE-4), with complementary equipment consisting of a waste feeding set (CAR) equipped with a dosing hopper (CAR-1) of rectangular prismatic shape with pyramidal lower end, connected to solid dosing screw (CAR-2) of helical shape, driven by mechanical drive assembly (CAR-2-A), output nozzle (CAR-2-B) connected to the suction nozzle of residues (CDS-1) from the solid disaggregator set (CDS) and dosing screw box (CAR-3); solid disintegrator assembly (CDS) equipped with residue suction nozzle (CDS-1), solid disintegration chamber (CDS-2), drive assembly (CDS-3), inspection nozzle with davit (CDS-4) , hot air inlet nozzle (CDS-5) connected to the hot air outlet duct (CA-3) of the air heating assembly (AC) and on the ferrule (CDS-9), coil (CDS-6) with internal electrical resistance, chains (CDS-7) with false links (CDS-7-A) near the outer end of the chain, product disaggregated output nozzles with air and steam (CDS-8) connected to the aggregated product duct set dried with air and steam (DP) and in the ferrule (CDS-9), ferrules (CDS-9) with a circular shape positioned inside the solids disintegration chamber (CDS-2); air heating set (AC) equipped with fan (CA-1), air heater (CA-2) composed of electrical resistance (CA-2-A) inside, hot air outlet duct (CA3) of rectangular prismatic shape and drive assembly (CA-4); and baffles (DP-1-A) inside the set of ducts for dry aggregated products with air and steam (DP) equipped with ducts (DP-1), connected to the nozzles at the inlet of dry disaggregated solid products with air and steam ( SPA-1).

[75] Alternatively, the raw material can be fed directly into the solid disaggregation chamber (CDS-2), of the set (CDS) in suspension or liquid form through the alternative waste feed set (CARA), equipped of the feed pump (CARA-1) connected to the feed duct (CARA-2) which is connected to the solids separator assembly (CDS).

[76] Alternatively, the chamber (CDS-2) of the solids separator assembly (CDS) can be increased in capacity by increasing the ferrule width (CDS-9) and increasing the number of streams (CDS-7).

[77] Alternatively, the coil (CDS-6) with internal electrical resistance may use electrical thermal inductor as a heating source.

[78] False links (CDS-7-A) are used from time to time to remove the final chain links that wear out and are replaced with new ones, facilitating and saving maintenance time and cost.

[79] The installation of the simultaneous deaggregator and dryer of the present patent takes place in the following sequence:

[80] i. The air heating assembly (AC), solids deaggregator assembly (CDS), the waste feeding assembly (CAR) or alternative waste feeding assembly (CARA), the solids deaggregating assembly (CDS) and the gaseous effluent (TE) treatment set at the installation site;

[81] ii. Connects and attaches the outlet nozzle (CAR-2-B) of the waste supply set (CAR) or the feed duct (CARA-2) of the set (CARA) to the waste suction nozzle (CDS) -1) of the solid disintegrator set (CDS);

[82] iii. Connect and fix the hot air inlet nozzle (CDS-5) of the solids separator assembly (CDS) to the hot air outlet duct (CA-3) of the air heating assembly (CA);

[83] iv. The air and steam (DP) dry deaggregated products duct assembly is fitted and fixed to the output nozzles (CDS-8) of the solids deaggregator assembly (CDS);

[84] v. The air and steam dry disaggregated products (DP) duct assembly is fitted and fixed to the air and steam dry disaggregated solid products inlet (SPA-1) of the air and dry disaggregated solid products separation assembly and steam (SPA);

[85] vi. The air and steam dry disaggregated solid product separation set (SPA) is connected to the gaseous effluent treatment set (TE) through the steam air inlet ducts (TE-1), steam air inlets ( TE-2) of the gaseous effluent treatment set (TE); and

[86] vii. Connect the product inlets (TS1) of the solids conveyor assembly (TS) to the product outlet valves (SPA-3) of the air and steam dry deaggregated solids products separation assembly (SPA).

• a) Liga-se o conjunto de aquecimento de ar (CA) para alimentar ar quente no conjunto desagregador de sólidos (CDS) via bocal de entrada de ar (CDS-5) e liga a energia elétrica para aquecimento das serpentinas (CDS-6);
• b) Carrega-se o material a ser processado na moega de dosagem (CAR-1) do conjunto de alimentação de resíduos (CAR) ou do conjunto de alimentação de resíduos alternativo (CARA);
• c) Liga-se o conjunto de acionamento (CAR-2-A) do conjunto de alimentação de resíduos (CAR) para que o material entre na câmara desagregadora (CDS-2);
• d) Liga-se o conjunto de acionamento (CDS-3) do conjunto desagregador de sólidos (CDS);
• e) Desagrega-se e seca-se o material ao mesmo tempo através do ar quente circulando no conjunto desagregador (CDS) e através do impacto das correntes de elos (CDS-7) que giram em alta velocidade, este movimento faz o material se chocar contra o caracol do equipamento provido de defletores tangenciais que fazem os materiais mudarem de direção impactando novamente com as correntes até ficarem no tamanho adequado e devido à alta velocidade tangencial e os defletores internos, ocorrendo alta frequência de vibração combinado com alta temperatura e devido a expansão dos gases gerados provocando a fricção, a calefação e a vaporização dos líquidos e os produtos processados e ar com vapores saem por duas aberturas existentes na parte superior do equipamento;
• f) Direciona-se o material processado através do conjunto de dutos (DP) o qual com suas chicanas (DP-1-A) para conjunto de separação de produtos sólidos desagregados secos do ar e vapor (SPA), direcionando-se o ar e vapor para o conjunto de tratamento de efluentes gasosos (TE) e direcionando-se o produto seco para a parte inferior interna dos ciclones (SPA-2) e deste para o conjunto transportador de sólidos (TS) para ser encaminhado para aplicação; e
• g) Libera-se o efluente tratado no conjunto de tratamento de efluentes gasosos (TE) através da chaminé (TE-4).

[87] The process performed by the deaggregator and dryer of the present patent follows the sequence:

• a) The air heating set (AC) is turned on to supply hot air to the solids deaggregator set (CDS) via the air inlet nozzle (CDS-5) and turn on the electrical energy for heating the coils (CDS-6 );
• b) The material to be processed is loaded into the dosing hopper (CAR-1) of the waste feeding set (CAR) or the alternative waste feeding set (CARA);
• c) Turn on the drive assembly (CAR-2-A) of the waste feed assembly (CAR) so that the material enters the deaggregating chamber (CDS-2);
• d) The drive assembly (CDS-3) of the solids deaggregator assembly (CDS) is turned on;
• e) The material is disaggregated and dried at the same time through the hot air circulating in the disintegrator assembly (CDS) and through the impact of the link chains (CDS-7) that rotate at high speed, this movement makes the material become crash into the snail of the equipment provided with tangential baffles that make the materials change direction, impacting again with the currents until they are in the proper size and due to the high tangential speed and the internal baffles, with a high frequency of vibration combined with high temperature and due to expansion of the gases generated causing friction, heating and vaporization of liquids and processed products and air with vapors exit through two openings in the upper part of the equipment;
• f) The processed material is routed through the set of ducts (DP) which with its baffles (DP-1-A) to the set of separation of dry disaggregated solid products from air and steam (SPA), directing the air and steam to the gaseous effluent treatment set (TE) and directing the dry product to the inner lower part of the cyclones (SPA-2) and from there to the solids conveyor set (TS) to be sent for application; and
• g) The effluent treated in the gaseous effluent treatment set (TE) is released through the chimney (TE-4).

• Aa1) O controlador lógico programável (CLP) examina as informações recebidas do sensor (HS) processa e retorna informações de parâmetros de funcionamento ao conjunto de aquecimento de ar (CA), e/ou ao conjunto de alimentação de resíduos (CAR) ou conjunto de alimentação de resíduos alternativo (CARA) e ao conjunto transportador de sólidos (TS) e/ou ao conjunto desagregador de sólidos (CDS);
• Aa2) O conjunto de aquecimento de ar (CA) recebe os parâmetros de funcionamento do controlador lógico programável (CLP) e controla a velocidade de rotação do ventilador (CA-1) via controlador e indicador de rotação (SIC-03) tipo variador de frequência ou similar e a temperatura e potencia do aquecedor de ar (CA-2) são controlados via sensores (TC-01) e (PC-02), respectivamente; e/ou
• Aa3) O conjunto de alimentação de resíduos (CAR) recebe os parâmetros de umidade do controlador lógico programável (CLP) e controla a velocidade de rotação do conjunto de acionamento mecânico (CAR-2-A) via controlador e indicador de rotação (SIC-01) tipo variador de frequência ou similar e o conjunto transportador de sólidos (TS) recebe os parâmetros de funcionamento do controlador lógico programável (CLP) e controla a velocidade de rotação do conjunto via controlador e indicador (SIC-04) tipo variador de frequência ou similar; e/ou
• Aa4) O conjunto desagregador de sólidos (CDS) recebe os parâmetros de umidade do controlador lógico programável (CLP) e controla a velocidade de rotação do conjunto de acionamento (CDS3) via controlador e indicador de rotação (SIC-02) tipo variador de frequência ou similar, e/ou a temperatura é controlada pelos sensores (TC02) e (PC-02), o (PC-02) recebe informações do controlador lógico programável (CLP) permitindo a alteração da potencia elétrica e consequentemente os parâmetros de temperatura dentro da câmara de desagregação de sólidos (CDS-2);

Bb) O nível de resíduo do conjunto de alimentação de resíduos (CAR) ou conjunto de alimentação de resíduos alternativo (CARA) são controlado via sensores de níveis (LSL-01) e (LSH01), os sensores de níveis (LSL-01) e (LSH-01) mandam informações ao controlador lógico programável (CLP) e esse emite parametros de funcionamento ao conjunto de acionamento mecânico (CAR-2-A) controlados via controlador e indicador de rotação (SIC-01) tipo variador de frequência ou similar;
Cc) O conjunto de tratamentos de efluentes gasosos (TE) manda informações de nível via sensores (LSL-02), (LSH-02), (LSL-03) e (LSH-03) às chaves de alimentação de energia (ES-01) e (ES02), liberando as válvulas de descarga de efluentes (DV-01) e (DV-02); e
Dd) As válvulas rotativas (VR-01) e (VR02) do conjunto de separação de produtos sólidos desagregados secos do ar e vapor (SPA) são acionadas manualmente.[88] The process control sequence is as follows:
Aa) The moisture sensor (HS) located on the solids conveyor assembly (TS) sends moisture information to the programmable logic controller (PLC) which at the same time controls the following:

• Aa1) The programmable logic controller (PLC) examines the information received from the sensor (HS) processes and returns operating parameter information to the air heater assembly (AC), and/or the waste supply assembly (CAR) or assembly alternative waste feed (CARA) and to the solids conveyor set (TS) and/or to the solids deaggregator set (CDS);
• Aa2) The air heating set (AC) receives the operating parameters from the programmable logic controller (PLC) and controls the fan rotation speed (CA-1) via the speed controller and indicator (SIC-03) type inverter. frequency or similar and the temperature and power of the air heater (CA-2) are controlled via sensors (TC-01) and (PC-02), respectively; and/or
• Aa3) The waste feed assembly (CAR) receives the moisture parameters from the programmable logic controller (PLC) and controls the rotation speed of the mechanical drive assembly (CAR-2-A) via the rotation controller and indicator (SIC- 01) type frequency variator or similar and the solids conveyor set (TS) receives the operating parameters of the programmable logic controller (PLC) and controls the rotation speed of the set via controller and indicator (SIC-04) type frequency variator or similar; and/or
• Aa4) The solids deaggregator assembly (CDS) receives the humidity parameters from the programmable logic controller (PLC) and controls the rotation speed of the drive assembly (CDS3) via the controller and rotation indicator (SIC-02) type frequency variator or similar, and/or the temperature is controlled by the sensors (TC02) and (PC-02), the (PC-02) receives information from the programmable logic controller (PLC) allowing the change of electrical power and consequently the temperature parameters inside the solids disintegration chamber (CDS-2);

Bb) The residue level of the residue feeding set (CAR) or alternative residue feeding set (CARA) are controlled via level sensors (LSL-01) and (LSH01), the level sensors (LSL-01) and (LSH-01) send information to the programmable logic controller (PLC) and this sends operating parameters to the mechanical drive set (CAR-2-A) controlled via controller and speed indicator (SIC-01) type frequency variator or similar;
Cc) The set of gaseous effluent treatments (TE) sends level information via sensors (LSL-02), (LSH-02), (LSL-03) and (LSH-03) to the power supply switches (ES- 01) and (ES02), releasing the effluent discharge valves (DV-01) and (DV-02); and
Dd) The rotary valves (VR-01) and (VR02) of the air and steam dry disaggregated solid products separation set (SPA) are manually activated.

Claims (6)

“Simultaneous WASTE DISAGGER AND DRYER”, equipped with a solid disaggregator set (CDS) type solids fractionator by vertical currents; set of ducts for dry disaggregated products with air and steam (DP) equipped with two metallic ducts (DP-1); air and steam dry disaggregated solid product separation set (SPA) equipped with air and steam dry disaggregated solid product inlet (SPA-1) of hollow rectangular prismatic shape with circular tip perpendicular to the body, of cyclones (SPA) -2) of hollow cylindrical shape, with a conical bottom, of product outlet valves (SPA-3) rotary or similar type, of air outlets with cyclone steam (SPA-4) of rectangular prismatic shape perpendicularly to the body; solid conveyor assembly (TS) type screw conveyor or similar connected to the product outlet valves (SPA-3) through the product inlets (TS-1); A gaseous effluent treatment set (TE) equipped with air inlet ducts with steam (TE-1) of hollow rectangular prismatic shape, air inlets with steam (TE-2) of hollow rectangular prismatic shape and perpendicular to the body, of gas washers (TE-3) of the retention or chemical and chimney type (TE-4), with complementary equipment, characterized by a waste feeding set (CAR) equipped with a dosing hopper (CAR-1) of prismatic format rectangular with pyramidal lower end, connected to solids dosing screw (CAR-2) of helical shape, driven by mechanical drive assembly (CAR-2-A), output nozzle (CAR-2-B) connected to the nozzle suction of residues (CDS-1) of the solid disaggregator set (CDS) and dosing screw box (CAR-3); solid disintegrator assembly (CDS) equipped with residue suction nozzle (CDS-1), solid disintegration chamber (CDS-2), drive assembly (CDS-3), inspection nozzle with davit (CDS-4) , hot air inlet nozzle (CDS-5) connected to the hot air outlet duct (CA-3) of the air heating assembly (AC) and on the ferrule (CDS-9), coil (CDS-6) with internal electrical resistance, chains (CDS-7) with false links (CDS-7-A) near the outer end of the chain, product disaggregated output nozzles with air and steam (CDS-8) connected to the aggregated product duct set dried with air and steam (DP) and in the ferrule (CDS-9), ferrules (CDS-9) with a circular shape positioned inside the solids disintegration chamber (CDS-2); air heating set (AC) equipped with fan (CA-1), air heater (CA-2) composed of electrical resistance (CA-2-A) inside, hot air outlet duct (CA-3 ) of rectangular prismatic shape and drive assembly (CA-4); and baffles (DP-1-A) inside the set of ducts for dry aggregated products with air and steam (DP) equipped with ducts (DP-1), connected to the nozzles at the inlet of dry disaggregated solid products with air and steam ( SPA-1). "Simultaneous Solids Disaggregation and Dryer", according to claim 1, characterized in that, alternatively, the raw material is fed directly into the solids disintegration chamber (CDS-2), of the assembly (CDS) in the form of suspension or it liquids through the alternative waste feed set (CARA), equipped with a feed pump (CARA-1) connected to the feed duct (CARA-2) which is connected to the solid deaggregator set (CDS). "Simultaneous solids deaggregator and dryer", according to claim 1, characterized in that, alternatively, the chamber (CDS-2) of the solids deaggregator assembly (CDS) has its capacity increased by increasing the width of the ferrule (CDS-9) and expanding the number of streams (CDS-7). "DRYER AND SIMULTANEOUS DRYER FOR SOLIDS", according to claim 1, characterized in that the false links (CDS-7-A) used from time to time to remove the links from final chains that wear out and are replaced by new ones. "PROCESS OF DEAGGREGATION AND SIMULTANEOUS DRYING OF SOLIDS", according to claim 1, characterized in that the process carried out by the deaggregator and dryer of the present patent takes place in the following sequence:

• a) The air heating set (AC) is turned on to supply hot air to the solids deaggregator set (CDS) via the air inlet nozzle (CDS-5) and turn on the electrical energy for heating the coils (CDS-6 );
• b) The material to be processed is loaded into the dosing hopper (CAR-1) of the waste feeding set (CAR) or the alternative waste feeding set (CARA);
• c) The activation set (CAR2-A) of the waste supply set (CAR) is turned on so that the material enters the deaggregating chamber (CDS-2);
• d) The drive assembly (CDS3) of the solids deaggregator assembly (CDS) is turned on;
• e) The material is disaggregated and dried at the same time through the hot air circulating in the disintegrator assembly (CDS) and through the impact of the link chains (CDS-7) that rotate at high speed, this movement makes the material become crash into the snail of the equipment provided with tangential baffles that make the materials change direction, impacting again with the currents until they are in the proper size and due to the high tangential speed and the internal baffles, with a high frequency of vibration combined with high temperature and due to expansion of the gases generated causing friction, heating and vaporization of liquids and processed products and air with vapors exit through two openings in the upper part of the equipment;
• f) The processed material is routed through the set of ducts (DP) which with its baffles (DP-1-A) to the set of separation of dry disaggregated solid products from air and steam (SPA), directing the air and steam to the gaseous effluent treatment set (TE) and directing the dry product to the inner lower part of the cyclones (SPA-2) and from there to the solids conveyor set (TS) to be sent for application; and
• g) The effluent treated in the gaseous effluent treatment set (TE) is released through the chimney (TE-4).

"PROCESS OF CONTROL OF DISAGGREGATION AND SIMULTANEOUS DRYING OF SOLIDS", according to claim 1, characterized in that the process control takes place in the following sequence:
Aa) The moisture sensor (HS) located on the solids conveyor assembly (TS) sends moisture information to the programmable logic controller (PLC) which at the same time controls the following:

• Aa1) The programmable logic controller (PLC) examines the information received from the sensor (HS) processes and returns operating parameter information to the air heater assembly (AC), and/or the waste supply assembly (CAR) or assembly alternative waste feed (CARA) and to the solids conveyor set (TS) and/or to the solids deaggregator set (CDS);
• Aa2) The air heating set (AC) receives the operating parameters from the programmable logic controller (PLC) and controls the fan rotation speed (CA-1) via the speed controller and indicator (SIC-03) type inverter. frequency or similar and the temperature and power of the air heater (CA-2) are controlled via sensors (TC-01) and (PC-02), respectively; and/or
• Aa3) The waste feed assembly (CAR) receives the moisture parameters from the programmable logic controller (PLC) and controls the rotation speed of the mechanical drive assembly (CAR-2-A) via the rotation controller and indicator (SIC- 01) type frequency variator or similar and the solids conveyor set (TS) receives the operating parameters of the programmable logic controller (PLC) and controls the rotation speed of the set via controller and indicator (SIC-04) type frequency variator or similar; and/or
• Aa4) The solids deaggregator assembly (CDS) receives the humidity parameters from the programmable logic controller (PLC) and controls the rotation speed of the drive assembly (CDS3) via the controller and rotation indicator (SIC-02) type frequency variator or similar, and/or the temperature is controlled by the sensors (TC-02) and (PC-02), the (PC-02) receives information from the programmable logic controller (PLC) allowing the change of electrical power and consequently the parameters of temperature inside the solids disintegration chamber (CDS-2);

Bb) The residue level of the residue feeding set (CAR) or alternative residue feeding set (CARA) are controlled via level sensors (LSL-01) and (LSH01), the level sensors (LSL-01) and (LSH-01) send information to the programmable logic controller (PLC) and this sends operating parameters to the mechanical drive set (CAR-2-A) controlled via controller and speed indicator (SIC-01) type frequency variator or similar;
Cc) The set of gaseous effluent treatments (TE) sends level information via sensors (LSL-02), (LSH-02), (LSL-03) and (LSH-03) to the power supply switches (ES- 01) and (ES-02), releasing the effluent discharge valves (DV-01) and (DV-02); and
Dd) The rotary valves (VR-01) and (VR-02) of the air and steam dry disaggregated solid products separation set (SPA) are manually activated.

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