KR102231886B1 - Continuous in-put system of combustible wastes fuel in cement calcination facilities using specific gravity seperating of blow-sorting device equipped with negative pressure room and sorting drum - Google Patents

Abstract

The present invention relates to a continuous input system of combustible waste fuel in a cement calcination process using the specific gravity separation of a blow-sorting apparatus equipped with a negative pressure room and a rotary sorting drum. More specifically, the present invention relates to a continuous input system of combustible waste fuel in a cement calcination process using the specific gravity separation of a blow-sorting apparatus equipped with a negative pressure room and a rotary sorting drum, which are able to separate the combustible waste, which is used as an alternative fuel for the cement calcination process, into combustible hard or soft waste fuel by the specific gravity separation of the blow-sorting apparatus equipped with the negative pressure room and the sorting drum, to continuously and sustainably input the separated waste fuel into a cement calciner and/or a rotary kiln, and to operate the cement calcination process in a stable manner.

Description

Continuous in-put system of combustible wastes fuel in cement calcination facilities using specific gravity seperating of blow-sorting device equipped with negative pressure room and sorting drum}

The present invention relates to a system for continuous injection of combustible waste fuel in a cement firing process using a specific gravity separation of a wind separator equipped with a negative pressure chamber and a rotating sorting drum, and more specifically, a combustible waste used as an alternative fuel for the cement firing process. Stable cement firing by separating flammable hard or soft waste fuel by the specific gravity separation of a wind separator equipped with a negative pressure chamber and a sorting drum and continuously and sustainably putting it into a cement calciner and/or rotary kiln. The present invention relates to a continuous input system for combustible waste fuel in a cement firing process using the specific gravity separation of a wind separator equipped with a negative pressure chamber and a rotating sorting drum to operate the process.

In general, the cement sintering process is an important process in which powdered raw materials are heated in a large rotary kiln at a high temperature of about 700 to 2,000°C to produce a semi-finished cement clinker through various physical and chemical reactions. .

In particular, in the firing process, a preheating process is performed, and since the reduction in fuel cost, which accounts for about 30% of the cement manufacturing cost, is a reduction in the cement cost, currently all cement manufacturing processes employ a calciner for the preheating process. , The preheating process is performed by flowing a high-temperature gas generated in a burner of a rotary kiln into a lower portion of the calciner.

In other words, looking at the heat flow of the rotary kiln and the calciner, after combustion in the burner at the lower end of the rotary kiln, the generated high-temperature exhaust gas flows to the bottom of the calciner. , The high-temperature gas that has flowed is heated up to about 850° C. while rising by its own lifting force and the suction force of the induction ventilator, and the powdered raw material dropped from the top of the calciner is heated to about 850° C., and the rotary kiln passes through the calciner. The high-temperature powder raw material in (Rotary Kiln) gets hotter as it goes down as the inclined rotary kiln rotates, and when it reaches the bottom, clinker, a semi-finished cement product of about 1,450℃, is created.

At this time, the high-temperature clinker goes through an air cooling process, and since the air cooled the clinker is heated to about 850°C, this air flows back into the bottom of the calciner.

In addition, in addition to the air of a rotary kiln, bituminous coal is usually added to the calciner to generate high-temperature combustion heat, but in addition to this, LPG, bunker C oil, WDF, waste oil, waste synthetic resin, Combustible waste and/or sewage sludge, waste tire chips, urethane powder, and the like are used as fuels, and in recent years, in particular, a lot of technologies using flammable wastes such as waste synthetic resins have been developed.

Conventionally, looking at the cement manufacturing facility using combustible waste, Korean Patent Registration 10-0343115 (registration date June 21, 2002) describes a solid waste storage facility 11, a mixing facility 13, and a crusher 15. , A screen 16, an input hopper 22, a calciner 25, and a rotary kiln 29, and the waste mixing facility 13 is a hopper 31 for inputting waste by type, and a belt conveyor 32 ), and a combustible solid waste consisting of a hopper 33 for inputting a mixture of solid waste as a cement manufacturing process, at least two selected from the group consisting of waste synthetic rubber, waste synthetic resin, waste synthetic fiber, waste paper, and waste wood. After the solid waste is sorted and laid out for each type, it is mixed in the mixing facility 13 in consideration of the calorific value and the chlorine content of each, but the upper solid waste from the storage facility 11 through a specific loader, tong truck, or belt conveyor 12. Is stored in the input hopper 31 of the input hopper 31, and solid wastes are stored in the mixed input hopper 33 according to the characteristic mixing ratio through the speed adjustment of the feeder at the bottom of the input hopper 31, and the biaxial shear crusher 15 ) To exist as the desired solid waste mixture 20, and the waste 17 with coarse particles is caught through the screen 16 and returned to the mixing facility 13, and the solid waste mixture 20 A technical configuration is known in which the silver calcination furnace 25 and the raw material chute of the lowermost cyclone 24 of the preheating chamber are introduced.

In addition, Korean Patent Registration 10-0492810 (registration date May 24, 2005) includes the steps of selecting and drying combustible landfill wastes among wastes generated during landfill restoration or reorganization; Compressing the dried combustible landfill waste at room temperature; Storing the compressed combustible landfill waste in a storage; And quantitatively supplying the stored combustible landfill waste to the calciner of the cement factory or to the inlet of the kiln by a pneumatic transport, wherein the compressed combustible landfill waste is crushed to a size of 5 to 30 cm or packed with a weight of 500 kg or less. A method of using a combustible waste as an auxiliary fuel in cement production is known.

However, combustible wastes used in conventional cement facilities that use the waste as a preheating material are not classified according to their type, or cannot be incinerated if they do not meet the incineration standards. There was a fatal problem in that the process was stopped if it was not put into the preheating process.

There are known technologies for pretreatment of combustible waste developed to solve the problem of using the combustible waste as a fuel. In the wind power sorting device in Korean Patent Registration 10-0872643 (registration date December 1, 2008), A housing 10; An input conveyor (20) installed on the front surface (10a) of the housing (10) and injecting waste (1) into the housing (10); The non-combustible material (1a) having a heavy specific gravity among the waste material (1) that is installed in the housing (10) and discharged at a constant pressure falls freely, and the inflammable material (1b) having a light specific gravity is blown away from the rear of the housing (10). A blower 22 for separating the incombustible material 1a and the combustible material 1b; A magnetic drum 28 that is rotatably installed at a predetermined distance from the air outlet 26 of the blower 22 and adsorbs metallic debris having a light specific gravity from the incombustible material 22; A non-combustible material storage space 12 provided on the bottom of the housing 10 and accommodating a free-falling non-combustible material 1b; A combustible material storage space 14 which is partitioned behind the incombustible material storage space 12 and accommodates the combustible material 1b blown away from the rear of the housing 10 by the air pressure of the blower 22; An exhaust port 38 formed on the rear surface 10b of the housing 10 and discharging the air discharged from the blower 22 to the outside; One end is connected to the exhaust port 38, and the other end is connected to the main body 24 of the blower 22 while passing through the upper surface of the housing 10 to receive the air discharged from the exhaust port 38. (10) A wind power sorting device is known, characterized in that it comprises a circulation duct 40 that circulates inside.

In addition, in the wind sorting machine for classifying heavy and light waste in Korean Patent Registration 10-1077101 (registration date October 20, 2011), heavy waste or lightweight waste is input, and an input control valve that controls the input amount of waste. An inlet (10) in which (11) is installed; A separating pipe 20 installed under the inlet 10 and in which waste input through the inlet collides against an inner wall formed in a zigzag shape, thereby reducing a descending speed and dispersing agglomerated wastes; A blowing pipe 70 connected to the lower side of the separation pipe 20 and for blowing strong wind injected from the circulation fan 80 installed at one end thereof to the separation pipe 20; A first discharge port 30 formed at the lower end of the separating pipe 20, descending from the upper side, and discharging heavy heavy wastes such as bottles and cans that cannot be pushed up by the wind; A circulation fan 80 installed at one end of the blower pipe 70 to inject strong wind into the blower pipe 70; A classification unit 50 that is connected to the upper side of the separation pipe 20 and moves the lightweight waste raised by the wind injected from the blower pipe 70, and generates a cyclone rotating along the inner wall surface to classify the lightweight waste from the wind. )Wow; A second discharge port 40 formed at the lower end of the classification unit 50 to discharge the lightweight waste classified by the classification unit 50; A circulation pipe 60 installed on the upper side of the classification unit 50 and connected to the circulation fan 80 to circulate the wind and fine dust classified by the classification unit 50 toward the circulation fan; And a cyclone is formed by rotating the wind flowing in through the separation pipe 20 in the classification unit 50, and the classification unit 50 is Lightweight wastes are classified through a cyclone, and lightweight wastes such as paper or vinyl having a certain weight are discharged through the second outlet 40, and very light materials such as fine dust are discharged through the circulation pipe 60. A waste recycling closed circuit internal circulation wind sorting device, characterized in that flowing into the circulation fan 80, is known.

In addition, Korean Patent Registration No. 10-1225015 (registration date January 16, 2013) allows cutting to be separated from randomly collected waste into combustible waste and pretreated into waste that can be incinerated in the incinerator of the incinerator. The process of cutting missing waste with the saws 19a and 19b of the cutting device 11, and the waste vinyl, waste cloth, waste clothes, waste bags, and waste nets flowing into the hopper 25a with the cutting device 12. The cutting process and the process of crushing using the crushing device 13 to facilitate sorting of solids flowing into the hopper 25b from among wastes, and the cut, cut, and crushed wastes 21a, 21b, 21c When moving the conveyors 18a, 18b) and passing through the magnetic sorting device 14, the process of sorting ferrous metals, and when the wastes 21a, 21b, 21c, which have been sorted with ferrous metals, are insufficient in capacity to supply quantitatively The process of quantitatively supplying wastes 21a, 21b, 21c, 21d using a conveyor 18b along with waste 21d flowing into a separate hopper 25c to quantify waste, and wastes supplied in a quantitative manner The process of separating wastes by vibrating (21a, 21b, 21c, 21d) with a vibrating device 16, and the separated wastes 21a, 21b, 21c, 21d are introduced into the trommel 17, and the trommel 17 A method for pretreatment of incineration waste, characterized in that it consists of a process of separating foreign substances and the like by centrifugal force caused by rotation of ), is known.

In addition, Korean Patent Registration No. 10-1275192 (registration date June 10, 2013) includes the process of crushing combustible waste, the process of selecting iron from the shredded combustible waste, and converting the combustible waste from which iron is selected to the Bali of the Bali Panel. The process of sorting ferrous, non-ferrous, stone, and soil), the process of repairing and sorting wire and PVC solids from the combustible waste from which foreign materials are selected, the process of crushing the combustible waste from which foreign materials (ferrous, non-ferrous, stone, soil) are selected, The process of sorting pulverized combustible waste with wind power, the process of inhaling and transporting the combustible waste selected in the wind power screening process, and after the combustible waste is sucked, foreign substances (ferrous, non-ferrous, stone, soil) and wet combustible waste are removed. The process of sorting, the process of transferring the inhaled combustible waste to the storage via the cyclone, the process of sorting the dust from the combustible waste transferred to the storage by the cyclone, the process of drying the combustible waste in the storage room, the process of quantitatively molding the dried combustible waste A method of forming a solid fuel for combustible waste, characterized in that it consists of a process of transferring to and forming a combustible waste transferred to a molding machine into a solid, is known.

In addition, a dropping conveyor unit configured to transfer an object to and drop it downward in Korean Patent Registration No. 10-1904154 (registration date September 27, 2018); A carry-out conveyor unit which is horizontally spaced apart from the dropping position of the object of the drop-off conveyor unit and carries out some of the objects; A sorting drum unit located on the carry-out conveyor unit, sorting some of the objects to be dropped from the dropping conveyor unit by weight and sending them onto the carry-out conveyor unit; And located along the top of the take-out conveyor unit, configured to suck dust generated on the take-out conveyor unit to block outflow of the dust, and pass over the sorting drum unit to the top of the take-out conveyor unit. And a suction blowing unit configured to provide air sucked together, wherein the sorting drum unit includes: a drum body positioned at one end of the dropping conveyor unit; A sorting drum rotatably configured on the drum body; It is disposed on the circumference of the sorting drum, and protrusions are arranged on the surface of the object to increase the frictional resistance of light objects and the sorting drum to increase the proportion of combustible waste containing moisture on the carry-out conveyor unit. A sorting sheet that filters to sort by; And a drum driving unit connected to the drum to drive the sorting drum and fixed at a lower portion of the drum body, wherein the suction and blowing unit is positioned so that the dropping conveyor unit is internally disposed therein, and the A dust suction body having a plurality of suction openings formed at a bottom portion along an upper portion of the carry-out conveyor unit, and having suction spaces provided at upper portions of the suction openings; A plurality of dust suction units positioned above the dust suction body so as to be connected to the suction opening through the suction space; A suction duct positioned above the dust suction body and connected to the plurality of dust suction units; And a circulation blower connected to the suction duct so as to apply a suction force to the suction duct, and blows air sucked through the suction duct onto the sorting drum, wherein the dropping conveyor unit includes There is provided a drop control unit configured to be rotated so that the drop position of the object is adjusted so that the position can be fixed, and the drop control unit includes: a drop control plate; And a rotation control part connected to the drop control plate so that the rotation position of the drop control plate is adjusted.

In addition, a rotary sorting box configured to be rotatable by a driving unit in the Korean Patent Registration 10-2080716 (registration date February 18, 2020); A waste sorting device installed at the inlet side of the rotating sorting bin to insert waste into the rotating sorting bin, and collecting inorganic waste to the outside of the rotating sorting bin and scattering combustible waste toward the exit side of the rotating sorting bin; A washing water supply pipe installed inside the rotating separator and spraying washing water through a plurality of nozzles to wash inorganic substances attached to the combustible waste; A screen installed so as to be spaced apart from the inner surface of the rotating sorting bin in the inner direction of the rotating sorting bin to separate the washing water and inorganic matter generated by washing the combustible waste from the combustible waste; And a waste latching plate that is formed to protrude from the screen in the inner direction of the rotary sorting bin so that the combustible waste scattered toward the outlet by the waste sorting device is impacted so that the inorganic waste is secondarily separated, and the waste is jammed. As for the plate, a plurality of waste latching plates are installed along the rotation direction of the rotating sorting bin, and a plurality of plates are arranged at regular intervals from the entrance side of the rotating sorting bin toward the exit side, and the installation height is increased toward the exit side. Combustible waste, characterized in that it is arranged so as to be staggered from the entrance side to the exit side direction of the rotary sorting bin, and is configured so that the combustible waste falling from different positions according to the weight difference is selectively caught and impacted. A waste wind turbine sorting device capable of washing waste is known.

However, the above-described combustible waste pretreatment device or combustible waste pretreatment device using a wind sorter classifies the sorted combustible waste by type by non-combustible waste or specific gravity difference, but a separate transfer means after storing the classified combustible waste separately. There was a problem in that it had to be used as a fuel at the customer through the process, and in particular, when it was used as a combustible waste fuel in the cement sintering process, there was a problem in that the cement sintering process could not be stably operated due to a problem in that continuous supply could not be made.

[Patent Document 001] Korean Patent Registration 10-0343115 (Registration Date June 21, 2002) [Patent Document 002] Korean Patent Registration 10-0492810 (Registration Date May 24, 2005) [Patent Document 003] Korean Patent Registration 10-0872643 (Registration Date December 1, 2008) [Patent Document 004] Korean Patent Registration 10-1077101 (Registration Date Oct. 20, 2011) [Patent Document 005] Korean Patent Registration 10-1225015 (Registration Date January 16, 2013) [Patent Document 006] Korean Patent Registration 10-1275192 (Registration Date June 10, 2013) [Patent Document 007] Korean Patent Registration 10-1904154 (Registration Date September 27, 2018) [Patent Document 008] Korean Patent Registration 10-2080716 (Registration Date February 18, 2020)

In order to solve the above problems, the present invention separates the combustible hard or soft waste fuel by separating the combustible waste fuel used as an alternative fuel in the cement firing process by the specific gravity separation of a wind separator equipped with a negative pressure chamber and a rotating sorting drum, and calcination of cement. Cement firing process using the specific gravity separation of a wind separator equipped with a negative pressure chamber and a rotary sorting drum to stably operate the cement firing process by continuously and sustainably inputting it into a calculator and/or rotary kiln. This is a task to solve the continuous input system of combustible waste fuel.

In order to solve the above problems, the present invention provides a combustible mixed waste in which combustible hard wastes including waste synthetic resins, waste tires, waste rubber and household wastes and combustible soft wastes including waste vinyls and waste fibers are mixed at one end. The combustible mixed waste input part inputted by the installed conveyor and the suction air duct at the upper part so that the combustible mixed waste input from the combustible mixed waste input part are scattered into the inside are connected to the suction air duct to form a negative pressure. A negative pressure chamber separated into hard waste, and a rotating sorting drum installed between the combustible mixed waste input unit and the negative pressure chamber so that the combustible mixed waste input from the combustible mixed waste input unit overflows into the negative pressure chamber, and the input An air injection unit for injecting air from a lower portion of the combustible mixed waste input unit to an upper portion of the rotating sorting drum so that the combustible mixed waste is scattered into the negative pressure chamber through the overflow of the rotating sorting drum, and the negative pressure chamber. A combustible hard waste discharging part formed in the lower part of the negative pressure chamber separated from the rotating sorting drum so that the combustible hard waste having a heavy specific gravity among the combustible mixed wastes is discharged, and the specific gravity of the combustible mixed waste scattered into the negative pressure chamber. A combustible soft waste discharge part formed in the lower part of the negative pressure chamber remotely spaced apart from the rotating sorting drum to discharge the light flammable soft waste, and an air suction duct connected to the upper part of the negative pressure chamber so that a negative pressure is formed in the negative pressure chamber. , A suction fan connected to the air suction duct to suck air, a dust duct connected to the suction fan to remove dust from air sucked through the air suction duct and the suction fan, and a dust duct transferred through the dust duct. A wind classifier comprising a filter unit for removing dust from air; A combustible hard waste input unit having one end connected to the combustible hard waste discharge unit and the other end connected to a calciner so as to input the combustible light waste into the calciner; One end is connected to the combustible soft waste discharge unit and the other end is connected to the combustible soft waste discharge unit so that the combustible soft waste is injected into a calciner and/or a rotary kiln, and the other end is a calciner and/or a rotary kiln. The combustible waste fuel continuous injection system of the cement sintering process using the specific gravity separation of the wind sorter with a negative pressure chamber and a rotating sorting drum, including a combustible soft waste input unit connected to, is used as a means of solving the problem.

The combustible hard waste input unit comprises a homogenizing hopper connected to the combustible hard waste discharging unit and the homogenizing hopper to homogenize and store the combustible hard waste discharged from the combustible light waste discharging unit. In order to quantitatively supply the combustible hard waste homogenized from the above, a hard quantitative supply device composed of a belt feeder or a screw feeder, and the homogenized combustible hard waste input from the hard quantitative supply device are calcined. (Calciner) In order to inject air into the interior, it is configured to include a pneumatic injection device connected to the calciner as a means of solving the problem.

The combustible soft waste input unit is a homogenizing silo connected to the combustible soft waste discharging unit to homogenize and store the combustible soft waste discharged from the combustible soft waste discharging unit, and from the homogenizing silo. A soft quantitative feeder consisting of a rotary feeder or a screw feeder to quantitatively supply the homogenized combustible soft waste; The calciner and/or rotary kiln in order to inject air into the homogenized combustible soft waste input from the soft quantitative supply device into the calciner and/or rotary kiln. ) To be configured including a pneumatic injection device connected to the solution to the problem.

The combustible waste fuel continuous injection system of the cement firing process using the specific gravity separation of the wind separator equipped with a negative pressure chamber and a rotating sorting drum of the present invention includes a negative pressure chamber and a rotating sorting drum for combustible waste used as an alternative fuel for the cement firing process. By separating the flammable hard or soft waste fuel by the specific gravity separation of the wind sorter, it is an excellent way to stably operate the cement firing process by continuously and sustainably inputting it into the cement calciner and/or rotary kiln. It works.

1 is a cement firing process combustion process diagram by a continuous combustible waste fuel input system of the cement firing process of the present invention
Figure 2 is a schematic diagram of a wind sorter having a negative pressure chamber and a rotating sorting drum of the present invention
3 is an overall configuration diagram of a wind sorter having a negative pressure chamber and a rotating sorting drum according to the present invention
Figure 4 is a perspective view of the rotating drum seen from the negative pressure chamber of the present invention
5 is an enlarged perspective view of the rotating sorting drum as viewed from the negative pressure chamber of the present invention
6 is a schematic diagram of a combustible hard waste input unit and a combustible soft waste input unit connected to a wind separator equipped with a negative pressure chamber and a rotating sorting drum of the present invention

In the present invention, a combustible mixed waste in which combustible hard wastes including waste synthetic resins, waste tires, waste rubber and household wastes and combustible soft wastes including waste vinyls and waste fibers are mixed is introduced by a conveyor installed at one end. A negative pressure that is connected to a suction air duct at the top so that the combustible mixed waste input unit and the combustible mixed waste input from the combustible mixed waste input unit are scattered into the interior to form a negative pressure, and is separated into combustible soft waste and combustible hard waste by a specific gravity difference. A rotating sorting drum installed between the chamber, the combustible mixed waste input unit and the negative pressure chamber so that the combustible mixed waste input from the combustible mixed waste input unit overflows into the negative pressure chamber, and the combustible mixed waste input is rotated A specific gravity of the combustible mixed waste scattered into the negative pressure chamber and an air spraying part that injects air from the lower side of the combustible mixed waste input part to the upper direction of the rotating sorting drum so as to be scattered into the negative pressure chamber through the overflow of the sorting drum. A combustible hard waste discharge unit formed in the lower part of the negative pressure chamber separated from the rotating sorting drum to discharge this heavy combustible hard waste, and a combustible soft waste having a light specific gravity among the combustible mixed waste scattered into the negative pressure chamber. A combustible soft waste discharge unit formed in the lower portion of the negative pressure chamber that is remotely spaced from the rotating sorting drum to be discharged, an air suction duct connected to the upper portion of the negative pressure chamber so that a negative pressure is formed in the negative pressure chamber, and the air suction duct. A suction fan connected to suction air, a dust duct connected to the suction fan to remove dust from the air sucked through the air suction duct and the suction fan, and a dust duct connected to the suction fan to remove dust from the air transferred through the dust duct. A wind turbine separator comprising a filter unit; A combustible hard waste input unit having one end connected to the combustible hard waste discharge unit and the other end connected to a calciner so as to input the combustible light waste into the calciner; One end is connected to the combustible soft waste discharge unit and the other end is connected to the combustible soft waste discharge unit so that the combustible soft waste is injected into a calciner and/or a rotary kiln, and the other end is a calciner and/or a rotary kiln. The combustible waste fuel continuous input system of the cement sintering process using the specific gravity separation of the wind sorter having a negative pressure chamber and a rotating sorting drum, including a combustible soft waste input unit connected to, is a feature of the technology configuration.

The combustible hard waste input unit comprises a homogenizing hopper connected to the combustible hard waste discharging unit and the homogenizing hopper to homogenize and store the combustible hard waste discharged from the combustible light waste discharging unit. In order to quantitatively supply the combustible hard waste homogenized from the above, a hard quantitative supply device composed of a belt feeder or a screw feeder, and the homogenized combustible hard waste input from the hard quantitative supply device are calcined. (Calciner) It is a feature of the technical configuration that it is configured to include a pneumatic injection device connected to the calciner in order to inject air into the interior.

The combustible soft waste input unit is a homogenizing silo connected to the combustible soft waste discharging unit to homogenize and store the combustible soft waste discharged from the combustible soft waste discharging unit, and from the homogenizing silo. A soft quantitative feeder consisting of a rotary feeder or a screw feeder to quantitatively supply the homogenized combustible soft waste; The calciner and/or rotary kiln in order to inject air into the homogenized combustible soft waste input from the soft quantitative supply device into the calciner and/or rotary kiln. It is a feature of the technical configuration that is configured including a pneumatic injection device connected to).

Hereinafter, embodiments of the present invention and/or drawings will be described in detail so that those of ordinary skill in the art can easily implement the present invention. However, the present invention may be implemented in various different forms, and is not limited to the embodiments and/or drawings described herein.

First, referring to [Fig. 1], the cement firing process combustion process by the continuous injection system of combustible waste fuel in the cement firing process using the specific gravity separation of the wind separator equipped with a negative pressure chamber and a rotating sorting drum of the present invention is a calciner (Calciner ), in a rotary kiln and in a cooler, combustible soft wastes such as soft plastics can be selectively put into the calciner and rotary kiln due to the high combustion rate, and the combustion speed In general, combustible hard wastes such as hard plastics, which are slower, can affect product quality, so they are generally not put into rotary kilns.

In order to separate the combustible hard waste and combustible soft waste into the cement firing process, a configuration of a continuous combustible waste fuel injection system of a cement firing process using the specific gravity separation of a wind separator equipped with a negative pressure chamber and a rotating sorting drum of the present invention was examined. Looking at it, it is as shown in [FIG. 2] to [FIG. 3].

In other words, combustible mixed waste in which combustible hard wastes including waste synthetic resins, waste tires, waste rubber and household wastes and combustible soft wastes including waste vinyls and waste fibers are mixed by a conveyor installed at one end. The waste input unit 11 and the combustible mixed waste inputted from the combustible mixed waste input unit 11 are connected to the suction air duct 16 at the top so that the combustible mixed waste is scattered into the interior to form a negative pressure. The negative pressure chamber 14 separated into combustible hard waste, and the combustible mixed waste input section 11 and the combustible mixed waste input section 11 so that the combustible mixed waste input from the combustible mixed waste input section 11 overflows into the negative pressure chamber 14. Injecting the combustible mixed waste so that the rotating sorting drum 12 installed between the negative pressure chambers 14 and the input combustible mixed waste are scattered into the negative pressure chamber 14 through the overflow of the rotating sorting drum 12 The air injection unit 18 for injecting air from the lower part of the part 11 to the upper direction of the rotating sorting drum 12, and the combustible hard waste having a high specific gravity among the combustible mixed wastes scattered into the negative pressure chamber 14 The specific gravity of the combustible hard waste discharge unit 13 formed in the lower portion of the negative pressure chamber 14, which is separated from the rotating sorting drum 12 so as to be discharged, and the combustible mixed waste scattered into the negative pressure chamber 14 A combustible soft waste discharge part 15 formed in the lower part of the negative pressure chamber 14 that is remotely spaced from the rotating sorting drum 12 so that the light flammable soft waste is discharged, and a negative pressure is formed in the negative pressure chamber 14 An air suction duct 16 connected to the upper portion of the negative pressure chamber 14, a suction fan 17 connected to the air suction duct 16 to suck air, the air suction duct 16 and a suction fan A dust duct 19 connected to the suction fan 17 to remove dust from the air sucked through 17, and a filter unit 20 for removing dust from the air transferred through the dust duct 19 Is composed including The wind turbine separator 100 and; A combustible hard waste input unit 200 having one end connected to the combustible hard waste discharge unit and the other end connected to a calciner so as to input the combustible light waste into the calciner; One end is connected to the combustible soft waste discharge unit and the other end is connected to the combustible soft waste discharge unit so that the combustible soft waste is injected into a calciner and/or a rotary kiln, and the other end is a calciner and/or a rotary kiln. It is configured to include a; combustible soft waste input unit 300 connected to.

At this time, the rotating sorting drum 12 is installed between the combustible mixed waste input unit 11 and the negative pressure chamber 14, as shown in [Fig. 4] to [Fig. 5], and the rotating sorting drum ( 12) It is composed of a rotating drum so that the combustible mixed waste input from the combustible mixed waste input unit 11 is overflowed and scattered into the negative pressure chamber 14 by the air injection unit 18 that injects air upward. .

On the other hand, a combustible hard waste input unit 200 having one end connected to the combustible hard waste discharge unit and the other end connected to the calciner so as to input the combustible light waste into the calciner; One end is connected to the combustible soft waste discharge unit and the other end is connected to the combustible soft waste discharge unit so that the combustible soft waste is injected into a calciner and/or a rotary kiln, and the other end is a calciner and/or a rotary kiln. The system configuration diagram of the combustible soft waste input unit 300 connected to is as shown in [Fig. 6].

Referring to Fig. 6, the combustible hard waste input unit 200 is a homogenization hopper connected to the combustible hard waste discharging unit to homogenize and store the combustible light waste discharged from the combustible hard waste discharging unit (Homogenizing Hopper) 201, and a rigid quantitative supply consisting of a belt feeder or a screw feeder to quantitatively supply the homogenized combustible hard waste from the homogenizing hopper 201 A device 202 and a pneumatic injection device 203 connected to the calciner to inject air into the homogenized combustible hard waste introduced from the light quantitative supply device 202 into the calciner. ).

In addition, referring to FIG. 6, the combustible soft waste input unit 300 is connected to the combustible soft waste discharging unit in order to homogenize and store the combustible soft waste discharged from the combustible soft waste discharging unit. Homogenizing silo (301) and a soft quantification consisting of a rotary feeder or screw feeder to quantitatively supply the homogenized combustible soft waste from the homogenizing silo 301 A supply device 302; The calciner and/or rotary kiln for air injection and injection of the homogenized combustible soft waste input from the soft quantitative supply device 302 into a calciner and/or rotary kiln. It is configured to include a pneumatic injection device 303 connected to the (Rotary Kiln).

The combustible waste fuel continuous injection system of the cement firing process using the specific gravity separation of the wind separator having a negative pressure chamber and a rotating sorting drum of the present invention constructed as described above, rotates the flammable waste used as an alternative fuel for the cement firing process with the negative pressure chamber. The cement sintering process is stably operated by separating the flammable hard or soft waste fuel by separating the specific gravity of the wind separator equipped with a sorting drum and continuously and sustainable inputting it into the cement calciner and/or rotary kiln. There is an excellent effect that can be operated.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments and/or drawings disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments and/or drawings. . The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

11: combustible mixed waste input section
12: rotating sorting drum
13: combustible hard waste discharge unit
14: negative pressure chamber
15: combustible soft waste discharge unit
16: air suction duct
17: suction fan
18: Air injection part
19: dust duct
20: filter unit
100: wind separator
200: combustible hard waste input unit
201: Homogenizing Hopper
202: light quantitative supply device
203: pneumatic injection device
300: combustible soft waste input unit
301: Homogenizing silo
302: soft quantitative supply device
303: pneumatic injection device

Claims (3)

Inflammable mixed waste that is mixed with combustible hard waste including waste synthetic resins, waste tires, waste rubber and household waste, and combustible soft waste including waste vinyl and waste fibers by a conveyor installed at one end. A negative pressure chamber is connected to an air suction duct in the upper part so that the combustible mixed waste inputted from the buwa and the combustible mixed waste input unit is scattered into the interior, so that a negative pressure is formed, and a negative pressure chamber is separated into combustible soft waste and combustible hard waste by a specific gravity difference, and the combustible mixed waste. A rotating sorting drum installed between the combustible mixed waste input part and the negative pressure chamber so that the combustible mixed waste input from the mixed waste input part overflows into the negative pressure chamber, and the input combustible mixed waste overflows the rotating sorting drum. An air injection unit that injects air from the bottom of the combustible mixed waste input unit toward the top of the rotating sorting drum so that it is scattered into the negative pressure chamber through the air, and the combustible hard material having a heavy specific gravity among the combustible mixed waste scattered into the negative pressure chamber. A combustible hard waste discharging part formed in the lower part of the negative pressure chamber separated from the rotating sorting drum so that waste is discharged, and the combustible soft waste having a light specific gravity among the combustible mixed waste scattered into the negative pressure chamber are discharged. A combustible soft waste discharge part formed in the lower part of the negative pressure chamber separated from the sorting drum, an air suction duct connected to the upper part of the negative pressure chamber so that a negative pressure is formed in the negative pressure chamber, and an air suction duct connected to the air suction duct to remove air. A suction fan for suction, a dust duct connected to the suction fan to remove dust from air sucked through the air suction duct and the suction fan, and a filter unit to remove dust from the air transferred through the dust duct. A wind power classifier configured by doing so; A combustible hard waste input unit having one end connected to the combustible hard waste discharge unit and the other end connected to a calciner so as to input the combustible light waste into the calciner; One end is connected to the combustible soft waste discharge unit and the other end is connected to the combustible soft waste discharge unit so that the combustible soft waste is injected into a calciner and/or a rotary kiln, and the other end is a calciner and/or a rotary kiln. It is configured to include a; combustible soft waste input unit connected to,
The combustible hard waste input unit comprises a homogenizing hopper connected to the combustible hard waste discharging unit and the homogenizing hopper to homogenize and store the combustible hard waste discharged from the combustible light waste discharging unit. In order to quantitatively supply the combustible hard waste homogenized from the above, a hard quantitative supply device composed of a belt feeder or a screw feeder, and the homogenized combustible hard waste input from the hard quantitative supply device are calcined. (Calciner) It is configured to include a pneumatic injection device connected to the calciner in order to inject air into the interior,
The combustible soft waste input unit is a homogenizing silo connected to the combustible soft waste discharging unit to homogenize and store the combustible soft waste discharged from the combustible soft waste discharging unit, and from the homogenizing silo. A soft quantitative feeder consisting of a rotary feeder or a screw feeder to quantitatively supply the homogenized combustible soft waste; The calciner and/or rotary kiln in order to inject air into the homogenized combustible soft waste input from the soft quantitative supply device into the calciner and/or rotary kiln. A continuous input system for combustible waste fuel in the cement sintering process using the specific gravity separation of a wind sorter equipped with a negative pressure chamber and a rotating sorting drum, comprising a pneumatic injection device connected to) delete delete

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