The present invention relates to a eco-friendly ultra-high temperature thermal decomposition system for waste-to-energy, more specifically, where its thermal decomposition chamber, made with special castable mixture designed to endure up to 1,800° C., maintains the ultra-high temperature above 850° C. and ten (10) layers of air curtains, made by a double-layered air-curtain maker installed at the center of the thermal decomposition chamber, allow the input materials to be completely decomposed without any auxiliary fuel and air pollutants to be completely decomposed by trapping them inside the thermal decomposition chamber with ultra-high temperature above 850° C. for more than two (2) seconds of residence time. Central oil nozzles and lower oil nozzles, installed on the center part and the lower part of inner wall of the thermal decomposition chamber to aim the central part and the bottom part of the thermal decomposition chamber, evenly spray the auxiliary fuel when necessary so the input materials with different conditions, sizes, and hydration level, are completely decomposed. Treatment capacity is improved through outer shredder installed at the left side of the thermal decomposition chamber, homogenizing the input materials with different conditions, sizes, and hydration level prior to feeding, and screw conveyor connecting the outer shredder and the thermal decomposition chamber automatically inputting the input materials. The input materials and ash that are not fully decomposed yet piled up at the bottom of the thermal decomposition chamber are shredded by inner shredder installed at the bottom part of the thermal decomposition chamber. After being shredded by the inner shredder, they are re-input into the thermal decomposition chamber via screw conveyor connecting the inner shredder and the thermal decomposition chamber, thus even the ash is also completely decomposed. Thermal generation chamber is composed around the thermal decomposition chamber and on the upper cover of the thermal decomposition chamber where thermal generation modules are installed within to effectively collect the waste heat generated from the thermal decomposition process so as to generate electricity. The waste heat generated from the thermal decomposition process also is used to generate steam via steam chamber installed within the upper cover of the thermal decomposition chamber, where such steam is sent to separately composed boiler and steam turbine via steam pipe to generate further electricity. The dust collector and the monitoring device are located at the right side of the thermal decomposition chamber with their collecting holes at the top part of inner wall of the thermal decomposition chamber to collect the dust when necessary and the air samples to monitor the results of the thermal decomposition process in real time.
The modern society is experiencing a sharp increase of waste generation caused by various factors including increasing population, urbanization, and commercialization. The generation of plastic wastes are especially drastic. According to UNEP, the weight of waste plastics in the ocean will be equivalent with the weight of entire sea creatures by 2050.
In general, the most advertised and prioritized ways of disposal of wastes are segregation and recycling. However, the actual recycling rate is extremely low simply because recycling is very hard in reality: the wastes should be rinsed and not contaminated to be recycled. Thus, most of the wastes are being disposed by sanitary landfills or big-scaled incinerators. Environmental problems and social problems from these ways of disposal have become issues for many countries. Sanitary landfill requires a huge amount of land, numbers of heavy equipment for operation and maintenance, and a huge initial investment for operation and management, while it also causes severe soil pollution, water pollution and air pollution by generating landfill gas, biogas, greenhouse gas, leachate, and other pollutants. Big-scaled incinerators also cause serious pollution because of air pollutants generated from the incineration, which leads to the huge initial investment cost for installation, operation, and management because the facility inevitably becomes enlarged with multiple combustion chambers and back-end pollution control system to remove air pollutants as well as the ash treatment facility to prevent the soil pollution that untreated ash causes.
Because of the problems of these conventional ways of disposal, various inventions such as low-temperature thermal decomposition system have been proposed; however, they still cause air pollution, even when they are enlarged and complicated with secondary combustion chamber in addition to the primary combustion chamber and the back-end pollution control system attached to the main system. The ash treatment system is still required, too. Other problems such as failing to evenly or completely combusts input materials with different conditions, sizes, and hydration level also occur, which requires a huge amount of auxiliary fuel to complement the system. Such use of auxiliary fuel ultimately reduces the efficacy and economic benefits of having alternative disposal system. Separate tools are also required to forcibly mix and combust the wastes piled up at the bottom part of the chamber, where the auxiliary fuel cannot reach. Moreover, when the wastes are shredded prior to feeding, it requires additional shredding process and equipment. Lastly, the waste heat generated during the operation are not utilized.
This present invention is proposed to resolve the problems mentioned above.
This present invention relates to a eco-friendly ultra-high temperature thermal decomposition system for waste-to-energy, where its thermal decomposition chamber, made with special castable mixture designed to endure up to 1,800° C., maintains the ultra-high temperature above 850° C. and ten (10) layers of air curtains made by air-curtain maker installed at the center of the thermal decomposition chamber allows the input materials to be completely decomposed without any auxiliary fuel and air pollutants to be completely decomposed by trapping them inside the thermal decomposition chamber with ultra-high temperature above 850° C. for more than two (2) seconds of residence time.
This present invention relates to a eco-friendly ultra-high temperature thermal decomposition system for waste-to-energy, where its central oil nozzles and lower oil nozzles, installed on the center part and the lower part of the inner wall of the thermal decomposition chamber respectively, each installed to aim the central part and the bottom part of the chamber, evenly spray the auxiliary fuel when necessary so the input materials with different conditions, sizes, and hydration level, can be completely decomposed; where its treatment efficacy is improved through the outer shredder installed at the left side of the thermal decomposition chamber, homogenizing the input materials with different conditions, sizes, and hydration level, and screw conveyor connecting the outer shredder and the thermal decomposition chamber automatically inputting the input materials; and where its inner shredder installed at the bottom part of the thermal decomposition chamber shreds the input materials and ash that are not fully decomposed yet piled up at the bottom of the thermal decomposition chamber so the screw conveyor connecting the inner shredder and the thermal decomposition chamber can re-input such materials back to the system, thus even the ash is also completely decomposed.
The present invention relates to a eco-friendly ultra-high temperature thermal decomposition system for waste-to-energy, where its thermal generation chamber is composed around the thermal decomposition chamber and on the upper cover of the thermal decomposition chamber and has thermal generation modules installed within effectively collect the waste heat generated from thermal decomposition process to generate electricity and the waste heat is also used to generate steam via the steam chamber installed within the upper cover of the thermal decomposition chamber, where such steam is sent to separately composed boiler and steam turbine via the steam pipe to generate further electricity.
The present invention relates to a eco-friendly ultra-high temperature thermal decomposition system for waste-to-energy, where its dust collector and the monitoring device are located at the right side of the thermal decomposition chamber with their collecting holes at the top part of inner wall of the thermal decomposition chamber to collect the dust when necessary and the air samples to monitor the results of the thermal decomposition process in real time.
To elaborate further on the distinct compositions of this present invention in order to achieve the above purposes, this present invention is distinctively composed with the thermal decomposition chamber, in a cylindrical shape made with special castable mixture designed to endure up to 1,800° C., which maintains ultra-high temperature above 850° C. even without any auxiliary fuel; the air-curtain maker in a double-layered design, with the outer pipe and the inner pipe, installed at the center of the thermal decomposition chamber with ten (10) vertical levels of air inlets, where 1st to 9th air inlets are connected to the inner pipe and the top-most 10th air inlet is connected to the outer pipe, where air inlets in each level are placed horizontally with identical distance between them, to create a total of ten (10) layers of air curtains so as to completely decompose air pollutants by trapping them within the thermal decomposition chamber with a ultra-high temperature above 850° C. for more than two (2) seconds of residence time and prevent any air pollution; the central oil nozzles and the lower oil nozzles installed on the center part and the lower part of the inner wall of the thermal decomposition chamber respectively to evenly spray auxiliary fuel when necessary, especially when the input materials are of low calorific value or high hydration level; the outer shredder installed at the left side of the thermal decomposition chamber homogenizing the input materials by shredding them; the inner shredder installed at the bottom part of the thermal decomposition chamber shredding the input materials and ash remaining at the bottom of the thermal decomposition chamber to ensure complete decomposition of input materials, even the ash; the screw conveyor automatically feeding the wastes and ashes shredded by outer and inner shredders back to the thermal decomposition chamber; the thermal generation chamber installed around the thermal decomposition chamber and on the upper cover of the thermal decomposition chamber to generate electricity through thermal generation modules collecting waste heat generated from the thermal decomposition process; the steam chamber installed on the upper cover of the thermal decomposition chamber to generate further electricity by producing steam using waste heat and sending such heat to the separately installed boiler and steam turbine via the steam pipe; the dust collector to collect the dust at the top part of the thermal decomposition chamber when necessary; and the monitoring device installed on the right side of the thermal decomposition chamber to monitor the results of thermal decomposition process in real time.
This present invention is distinctively composed with the air-curtain maker in a double-layered design with the outer pipe and the inner pipe, where the inner pipe is connected to the inner blower installed on the right side of the thermal decomposition chamber and the outer pipe is connected to the outer blower installed on the right side of the thermal decomposition chamber. Such air-curtain maker has ten (10) vertical levels of air inlets, where air inlets in each level are placed horizontally, where the air inlets from the 1st to the 9th level, the 1st being the lowest, are connected to the outer pipe to create nine (9) layers of air curtains within the thermal decomposition chamber, while the top-most air inlet on the 10th level is connected to the inner pipe to create the top-most one (1) layer of air curtain, controlling and managing the below nine (9) layers of air curtains. Such ten (10) layers of air curtains trap both the input materials and the air pollutants generated from the thermal decomposition process within the thermal decomposition chamber with ultra-high temperature of 850° C. for more than two (2) seconds of residence time until they are completely decomposed.
This present invention is distinctively composed with the central oil nozzles and the lower oil nozzles where the central oil nozzles are installed on the center part of inner wall of the thermal decomposition chamber with three (3) nozzles, connected with auxiliary fuel tank via central oil nozzles supply pipe, aiming at the central part of the thermal decomposition chamber, while the lower oil nozzles are installed on the lower part of inner wall of the thermal decomposition chamber with three (3) nozzles, connected with auxiliary fuel tank via lower oil nozzles supply pipe, aiming at the bottom part of the thermal decomposition chamber. The central oil nozzles and the lower oil nozzles aim at the central and bottom part of the thermal decomposition chamber respectively and evenly spray auxiliary fuel without leaving any blind spot. The amount of auxiliary fuel sprayed into the thermal decomposition chamber can be controlled by the central oil nozzles control valve and the lower oil nozzles control valve.
This present invention is distinctively composed with the outer shredder installed at the left side of thermal decomposition chamber, connected with the thermal decomposition chamber via screw conveyor, to homogenize the input materials with different conditions, sizes, and hydration level, by shredding them prior to being fed into the thermal decomposition chamber, so as to reduce the volume of the input materials and improve the treatment capacity, while the inner shredder is installed at the bottom part of the thermal decomposition chamber, connected with the thermal decomposition chamber via screw conveyor, to shred the input materials that are not fully decomposed yet remaining and piled up at the bottom of the thermal decomposition chamber as well as the ash, so as to the screw conveyor connecting the inner shredder and the thermal decomposition chamber can re-input such materials back to the system, thus even the ash is completely decomposed. The screw conveyor is composed of vertical screw conveyor and horizontal screw conveyor, thus it can automatically re-input shredded input materials and ash from the outer shredder and the inner shredder. The screw conveyor is equipped with an extra layer of cooling pipe since the ash and remaining input materials at the bottom of the thermal decomposition chamber are still hot after being shredded by the inner shredder.
This present invention is distinctively composed with the thermal generation chamber, installed around the thermal decomposition chamber and on the upper cover of the thermal decomposition chamber, used to collect waste heat and generate electricity. More specifically, thermal generation modules are installed within the thermal generation chamber, where such modules effectively collect the waste heat generated from the thermal decomposition process and generate electricity. The thermal generation chamber around the thermal decomposition chamber has its thermal generation modules along the inner walls while the thermal generation chamber on the upper cover of the thermal decomposition chamber has thermal generation module plates on idle space to maximize the number of thermal generation modules attached, so as much waste heat as possible is collected.
This present invention is distinctively composed with the steam chamber, installed on the upper cover of the thermal decomposition chamber, with water supply pipe on the left side, heating pipe within the steam chamber, and steam pipe on the upper side of the steam chamber. The water is vaporized via waste heat generated from the thermal decomposition process and such steam is sent to separately composed boiler and steam turbine to generate further electricity via steam pipe. More specifically, the water is supplied into the steam chamber via the water supply pipe and is vaporized via waste heat generated from the thermal decomposition chamber, which is accelerated by the heating pipe within the steam chamber. Vaporized steam by waste heat and the heating pipe is sent to separately composed boiler and steam turbine to generate electricity via the steam pipe.
This present invention is distinctively composed with the dust collector, located at the right side of the thermal decomposition chamber with six (6) dust collecting holes at the top part of inner wall of the thermal decomposition chamber so the dust generated from the thermal decomposition process is collected by dust collecting holes and transferred via dust collecting pipes to the dust collecting chamber.
This present invention is distinctively composed with the monitoring device, located at the right side of the thermal decomposition chamber with one (1) collecting hole at the top part of inner wall of the thermal decomposition chamber so the samples are collected by collecting hole and transferred via monitoring pipe and the monitoring results of the thermal decomposition process are easily confirmed from the monitoring dashboard in real time.
This present invention, a eco-friendly ultra-high temperature thermal decomposition system for waste-to-energy, has an effect of complete thermal decomposition of the input materials without auxiliary fuel since its thermal decomposition chamber is made with special castable mixture designed to endure up to 1,800° C., which makes it capable of maintaining the ultra-high temperature above 850° C. inside without any auxiliary fuel.
This present invention has an effect of complete elimination of air pollutants since its air-curtain maker installed at the center of thermal decomposition chamber has ten (10) vertical levels of air inlets which create total of ten (10) layers of air curtains within the thermal decomposition chamber, and such multiple layers of air curtains trap the input materials and air pollutants inside the thermal decomposition chamber with ultra-high temperature above 850° C. for more than two (2) seconds of residence time so the air pollutants are also completely decomposed.
This present invention has an effect of complete thermal decomposition of the input materials since its central oil nozzles and lower oil nozzles installed on the inner wall of the thermal decomposition chamber evenly spray auxiliary fuel without any blind spot when needed, especially when the input materials are of different conditions, sizes, and hydration level, especially those of low calorific value or high hydration level.
This present invention has an effect of treatment efficacy improvement since its outer shredder installed at the left side of the thermal decomposition chamber, connected with the thermal decomposition chamber via a screw conveyor, reduces the volume of the input materials and homogenizes the input materials with different conditions, sizes, and hydration level, by shredding them prior to being fed into the thermal decomposition chamber.
This present invention has an effect of complete thermal decomposition of the input materials, even the ash, since its inner shredder installed at the bottom part of the thermal decomposition chamber, connected with the thermal decomposition chamber via screw conveyor, shreds the input materials that are not fully decomposed yet remaining and piled up at the bottom of the thermal decomposition chamber as well as the ash, so as to the screw conveyor connecting the inner shredder and the thermal decomposition chamber can re-input such materials back to the thermal decomposition chamber, thus even the ash is completely decomposed.
The present invention has an effect of maximization of electricity generation since the invention has two ways of electricity generation: the thermal generation chamber and the steam chamber. Its thermal generation chamber installed around the thermal decomposition chamber and on the upper cover of the thermal decomposition chamber, has the thermal generation modules installed within, to effectively collect the waste heat generated from the thermal decomposition process to generate electricity, as well as its steam chamber installed on the upper cover of the thermal decomposition chamber utilizes waste heat to generate steam via the water supply pipe and the heating pipe, so as such steam is sent to separately composed boiler and steam turbine to generate even more electricity.
This present invention has an effect of safe and rapid treatment of even infectious and medical wastes while generating electricity, since the invention, being compact and small, is the most suitable waste-to-energy facility for residential area or industrial complexes like a dense apartment complex in Korea and for countries composed of lots of small islands like the Philippines and Indonesia, unlike big and enormous conventional waste-to-energy plants which need to be away from the residential or industrial complexes and require huge amount of land. Since the invention treats the input materials in ultra-high temperature above 850° C., every pathogen, bacteria, and virus present within the materials are completely eradicated, which makes the invention the perfect solution for safe and rapid on-site treatment of infectious and medical wastes generated from hospitals, clinics, test centers for infectious diseases, and hospitals, even in advanced countries such as Korea, United States of America, Japan, and European countries.
This present invention has an effect of minimization of dust release and real time monitoring of its environmental impact since its dust collector collects every dust generated from the thermal decomposition process and its monitoring device provides real time monitoring data of the thermal decomposition process.
This present invention relates to a eco-friendly ultra-high temperature thermal decomposition system for waste-to-energy.
This present invention includes: thermal decomposition chamber 100 made with special castable mixture in a cylindrical shape designed to endure high temperature up to 1,800° C. and to maintain ultra-high temperature above 850° C. even without any auxiliary fuel; air-curtain maker 110 composed as double-layered design at the center of the thermal decomposition chamber with inner pipe 120 and outer pipe 130 and ten (10) vertical levels of air inlets designed to create ten (10) layers of air curtains so as to completely decompose air pollutants by trapping them within the thermal decomposition chamber 100 and prevent air pollution; central oil nozzles 140 and lower oil nozzles 150 installed on the inner wall of the thermal decomposition chamber 100 to evenly spray auxiliary fuel when necessary; outer shredder 170 installed at the left side of the thermal decomposition chamber 100 homogenizing the input materials by shredding them prior to feeding; inner shredder 180 installed at the bottom part of the thermal decomposition chamber 100 shredding the input materials and ash remaining at the bottom of the thermal decomposition chamber 100; screw conveyor 190 automatically feeding the input materials and ash shredded by the outer shredder 170 and the inner shredder 180 back to the thermal decomposition chamber 100; thermal generation chamber 200 installed around the thermal decomposition chamber 100 and on the upper cover 80 of the thermal decomposition chamber 100 to generate electricity by collecting waste heat generated from the thermal decomposition process; steam chamber 210 installed within the upper cover 80 of the thermal decomposition chamber 100 to generate further electricity by producing steam using waste heat and sending such heat to the separately installed boil and steam turbine via steam pipe 213; dust collector 300 to collect the dust at the top part of the thermal decomposition chamber 100 when necessary; and monitoring device 310 installed on the right side of the thermal decomposition chamber 100 to monitor the thermal decomposition process.
Hereinafter, embodiments of this present invention will be described in detail with reference to the accompanying drawings.
The thermal decomposition chamber 100 is a main element of this present invention, where the process of thermal decomposition itself happens and all the other elements are installed on and around as illustrated in
The thermal decomposition chamber 100 may have a cylindrical shape as illustrated in
The thermal decomposition chamber 100 has the upper cover 80 as illustrated in
Moving on to
It is also required for the air-curtain maker 110 to be made of a material with excellent heat and acid resistance since it is not only a functionally central element of the thermal decomposition process but also a physically central element of the thermal decomposition chamber 100 where the thermal decomposition process is happening, thus the temperature is the highest.
The air-curtain maker 110 has ten (10) vertical levels of air inlets, where air inlets in each level are placed horizontally with the same distance between each air inlet. The levels of air inlets and number of air inlets in each level may be adjusted as needed. Lower air inlets 133, from 1st to 9th level of air inlets, where 1st being the lowest, are connected to the outer pipe 130, blowing the air into the thermal decomposition chamber 100 from the outer blower 131. The top-most air inlet, 10th air inlet 123, is connected to the inner pipe 120, blowing the air into the thermal decomposition chamber from the inner blower 121. As illustrated in
The main purpose of the air-curtain maker 110 is to create air curtains, specifically, ten (10) layers of air curtains in this present invention, which may be adjusted as needed as well. Such air curtains play a major role in air pollution prevention since they trap not only the input materials but also the air pollutant materials which may be generated from the thermal decomposition process inside the thermal decomposition chamber 100. The air pollutants like dioxins are also thermally decomposed when they are exposed to ultra-high temperature above 850° C. for more than two (2) seconds of residence time. The air curtains elongate such residence time of air pollutant materials inside the thermal decomposition chamber 100 by literally creating multiple layers of curtains, thus creating barriers, so it is hard for air pollutant materials to escape from the thermal decomposition chamber 100. This eliminates the need for secondary decomposition or combustion chamber which is only needed to achieve such two (2) seconds of residence time. Moreover, such secondary decomposition chamber only causes the system to be unnecessarily bigger and enlarged. Because of the air curtains carefully designed and created by the air-curtain maker 110, the present invention can maintain its compact size.
Moving on to
The central oil nozzles 140 are connected to an auxiliary fuel tank 160 via central oil nozzles supply pipe 142. The amount of auxiliary fuel sprayed into the thermal decomposition chamber 100 can be adjusted via central oil nozzles control valve 141. The lower oil nozzles 150 are also connected to the auxiliary fuel tank 160 via lower oil nozzles supply pipe 152, with lower oil nozzles control valve 151 installed along the lower oil nozzles supply pipe 152 to adjust the amount of auxiliary fuel sprayed into the thermal decomposition chamber 100.
The main purpose of the central oil nozzles 140 and the lower oil nozzles 150 is to evenly spray auxiliary fuel without any blind spot to assist the thermal decomposition process when the input materials are of different conditions, sizes, and hydration level. Auxiliary fuel may be needed, particularly when the input materials have low calorific value due to lots of biodegradables or have higher hydration level for being medical wastes. In these cases, the central oil nozzles 140 and the lower oil nozzles 150 may be utilized to evenly spray auxiliary fuel into the thermal decomposition chamber 100 to boost the thermal decomposition process of such materials without leaving any blind spots.
Another important feature of the central oil nozzles 140 and the lower oil nozzles 150 is that each nozzle can be meticulously controlled and operated separately from the other nozzles to earn the optimal result. With control panel 90 on the right side of the thermal decomposition chamber 100, it is possible to turn on only one central oil nozzle from the central oil nozzles 140, while it is also possible to turn on one nozzle each from the central oil nozzles 140 and the lower oil nozzles 150.
As illustrated in
The inner shredder 180 is located at the bottom part of the thermal decomposition chamber 100. It is a very common phenomenon that the input materials are piled up together with the ash at the bottom, especially on the bottom edge of the thermal decomposition chamber 100, and are not being treated anymore. In order to prevent this piling up of untreated input materials and ash and to achieve complete thermal decomposition, the inner shredder 180 shreds those piled up input materials and ash, so as those shredded remaining input materials and ash can be re-input into the thermal decomposition chamber 100 via the screw conveyor 190. The inner shredder 180 may also be equipped with inner shredder inspection door 181.
It is also preferable that the shredding blades of the inner shredder 180 are of material with rust preventive characteristic and excellent heat and acid resistance since they are exposed to the high temperature above 850° C. inside the thermal decomposition chamber 100.
Screw conveyor 190 is composed of horizontal screw conveyor 191 connecting the outer shredder 170 and the inner shredder 180 to vertical screw conveyor 192, thus the shredded materials can be transported horizontally and then vertically up to input door 193 installed at the top part of the thermal decomposition chamber 100 and fed into the thermal decomposition chamber 100 through the input door 193.
It is also important to note that the screw conveyor 190 is covered with a layer of cooling pipe 194. The method of cooling may be air-cooling or water-cooling, the cooling method may be decided based on the unique circumstances of each installation. The cooling pipe 194 is needed since the remaining input material and ash piled up on the bottom of the thermal decomposition chamber 100 are still of high temperature even after being shredded. In order to prevent unnecessary tear and wear of the screw conveyor 190, the cooling pipe 194 is installed to cool down such shredded remaining input material and ash.
Moving on to
The steam chamber 210 is composed on the upper cover 80 of the thermal decomposition chamber 100. The main purpose of steam chamber 210 is to utilize the waste heat generated from thermal decomposition process to produce steam and to send such steam to the separately installed boiler and steam turbine for further power generation. The steam chamber 210 produces steam by supplying water into the steam chamber 210 via water supply pipe 211. The water supplied into the steam chamber 210 is boiled and vaporized by waste heat from the thermal decomposition chamber 100, while heating pipe 212 installed inside the steam chamber 210 assists such steam production by providing extra source of heat. The steam produced from the steam chamber 210 is then transferred to the boiler and steam turbine via steam pipe 213. The steam may also be transferred to different applications via steam pipe 213 where such steam is needed based on circumstances of each installation.
As illustrated in
The monitoring device 310 located at the right side of the thermal decomposition chamber 100 also plays an important role for air pollution monitoring, with one (1) collecting hole 311 at the top part of inner wall of the thermal decomposition chamber 100, above the top-most air curtain created by 10th air inlets 123. After air pollutant materials are completely thermally decomposed by ten (10) layers of air curtains trapping them in an environment with ultra-high temperature above 850° C. for more than two (2) seconds, the result shall be monitored in real-time via the monitoring device 310. The samples are collected via collecting hole 311 and transferred via monitoring pipe 312 to the monitoring device 310 on the right side of the thermal decomposition chamber 100. The result of such thermal decomposition process will be shown in the monitoring dashboard 313 on the monitoring device 310.
The control panel 90, that all illustrations show, is used to control every element of the present invention from the upper cover 80, the air-curtain maker 110, both the inner pipe 120 and the outer pipe 130, the central oil nozzles 140, the lower oil nozzles 150, the outer shredder 170, the inner shredder 180, the screw conveyor 190, the thermal generation chamber 200, the steam chamber 210, the dust collector 300, and monitoring device 310.
While certain embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to the abovestated embodiments, and it should be understood that we intend to cover the present invention design modifications, additions and substitutions, without departing from the spirits of the present invention.
The drawings are to be regarded as illustrative in nature and not restrictive. For convenience of understanding of the elements, sizes, or thicknesses in the drawings may be exaggerated and enlarged, may be expressed to be small, or may be simplified for clarify of illustration.
Lastly, the same reference numerals used throughout the drawings and the description refer to the same or like elements or parts.
Number | Date | Country | Kind |
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10-2021-0088168 | Jul 2021 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/KR2022/009627 | 7/4/2022 | WO |