KR20110056896A - Pyrolytic energy recovery system using heat from burning wastes - Google Patents

Abstract

PURPOSE: A PER(Pyrolytic Energy Recovery) system for waste articles is provided to reduce environmental contamination and efficiently utilize energy by carrying out pyrolysis of wasted articles using the heat generated from incineration of waste and completely burning combustion gas produced during incineration of waste. CONSTITUTION: A PER system for waste articles comprises a pyrolytic furnace(200) in which incineration of waste and pyrolysis of recyclable waste articles take place. The pyrolytic furnace includes a heating chamber(220) in which incinerated waste is burned and a pyrolytic chamber(230) in which plastic wasted articles are pyrolyzed by the heats generated from the waste incineration in the heating chamber and the operation of a main burner(222). The pyrolysis gas is discharged through a vapor outlet(238), and the residue of pyrolysis is discharged from the pyrolytic chamber through a residue discharge screw(236).

Description

Pyrolytic energy recovery system using heat from burning wastes

The present invention relates to a pyrolysis energy recovery apparatus for waste products using waste incineration heat, and more particularly, to waste waste incineration heat to recover useful energy from waste materials made of synthetic resin using incineration heat generated in the process of burning waste. The present invention relates to a pyrolysis energy recovery apparatus for used waste products.

Pyrolytic Energy Recovery System (PER) using pyrolysis of waste products reduces environmental pollution by considering environmental pollution and waste of resources caused by incineration of waste materials from synthetic resin raw materials. Rather, it is designed to enable the recycling of resources.

1 is a view showing an example of an energy recovery apparatus using pyrolysis of conventional waste products. As shown in the drawing, the energy recovery apparatus 10 using pyrolysis of conventional waste products has a pyrolysis furnace 20 in which an inner space is divided into a heating chamber 22 and a pyrolysis chamber 24 with a heat plate 26 therebetween. It is made, including. On the other hand, a waste inlet 28 through which the waste to be processed is disposed is provided on the upper side of the pyrolysis chamber 24 of the pyrolysis chamber 20, while the waste is injected evenly into the pyrolysis chamber 24 below the waste inlet 28. The rotary 30 is installed to be distributed. In addition, a gas discharge pipe 32 is installed at the upper side of the pyrolysis chamber 24 to discharge the gas generated as the waste is pyrolyzed by the high temperature heat transmitted from the heating chamber 22, while on the heat plate 26. Residual discharge screws 34 which guide the residue after thermal decomposition to be discharged to the outside are installed at regular intervals.

The operation of the energy recovery device 10 using the pyrolysis of the conventional waste product configured as described above will be briefly described as follows. First, as the burner 36 installed on the side of the heating chamber 22 is operated, the temperature inside the pyrolysis chamber 24 is increased, and the wastes introduced through the waste inlet 28 are decomposed by high temperature heat. The generated gas is discharged through the gas discharge pipe 32, while the residue after the thermal decomposition is discharged to the outside through the residue discharge screw 34. On the other hand, the gas discharged through the gas discharge pipe 32 is extracted into the oil of the liquid component while passing through devices such as condensers, coolers.

On the other hand, the heat of combustion and combustion gas passing through the heating chamber 22 of the above-described pyrolysis furnace 10 is discharged to the outside through the combustion heat discharge pipe 40 provided on the upper center side of the pyrolysis furnace 10.

However, the conventional energy recovery device using pyrolysis of waste products was used only to recover useful energy through pyrolysis of waste products, but the combustion heat passing through the heating chamber is discharged to the outside as it is improved in terms of efficient use of energy. Was needed.

In addition, the conventional energy recovery device using pyrolysis of waste products has disadvantages in terms of energy saving since only a burner for burning fuel such as gas or oil is used as a heat source for pyrolysis of waste products.

Therefore, the present invention has been made in order to solve the problems of the prior art as described above, waste incineration heat which can save energy by using the incineration heat generated in the process of burning waste as a heat source for pyrolysis of waste products It is an object of the present invention to provide a pyrolysis energy recovery apparatus for waste products.

Another object of the present invention is to thermally decompose a recycled raw material of a synthetic resin system in a high temperature pyrolysis chamber to extract useful renewable energy, as well as using waste incineration heat that can produce hot water by using a high temperature provided for pyrolysis of the recycled raw material. It is to provide a pyrolysis energy recovery device of the waste.

The present invention configured to achieve the above object is as follows.

According to the present invention, the interior of the pyrolysis furnace is divided into a heating chamber and a pyrolysis chamber with a heat plate interposed therebetween, while a waste inlet is installed on the upper side of the pyrolysis chamber, while a rotary in the pyrolysis chamber can be spread evenly. Installed on the heat plate, the residue discharge screw for discharging the residue is installed, the wastes put into the pyrolysis chamber are pyrolysis by heating of the main burner installed in the heating chamber, the wastes are configured to extract useful oil components In the pyrolysis energy recovery apparatus of the present invention, a waste conveying screw is installed across a lower portion of the heating chamber, and a waste inlet is installed at one end of the waste conveying screw on the side where the waste flows into, while one end of the waste conveying screw is burned. Residues of garbage It means that the waste incineration residues garbage discharge port is installed so that waste incineration injected by the main burners set in the heating chamber; Combustion gas ducts are installed on the side of the heating chamber so that the combustion gas generated in the process of incineration of waste by the main burner installed in the heating chamber is discharged to the outside; The cylindrical housing is installed on the side of the pyrolysis furnace, and the end of the combustion gas duct is connected to the lower side of the housing while the spiral circulation is maintained until the combustion gas introduced through the combustion gas duct is discharged to the exhaust port provided at the upper part of the housing. A boiler having a water heating burner installed at one side of the housing such that a spiral flow path is installed therein so as to guide the heated water through the water supply pipe installed inside the heating chamber; And a combustion gas heat exchanger installed behind the exhaust port of the boiler to condense the combustion gas passing through the exhaust port of the boiler. The configuration is made, including.

The combustion gas condensed by the auxiliary burner on one side of the combustion gas heat exchanger in order to burn the combustion gas condensed through the combustion gas heat exchanger in the pyrolysis energy recovery apparatus of the waste using incineration heat according to the present invention close to the complete combustion. The burning final combustor is further installed.

In the pyrolysis energy recovery apparatus for waste products using waste incineration heat according to the present invention, pyrolysis furnaces are installed on both sides of the boiler, but the combustion gas ducts, which are pipes between the boiler and the pyrolysis furnace, are pipes in a 'X' shape on a plane.

In the pyrolysis energy recovery apparatus for waste products using waste incineration heat according to the present invention, a heating chamber is provided with a plurality of sets of two waste conveying screws, and a partition wall for inducing the flame direction of the main burner is provided between the two sets of waste conveying screws. It is installed in a certain length.

In the pyrolysis energy recovery apparatus for waste products using waste incineration heat according to the present invention, the water supply pipe of the section in which the partition wall is located in the section of the water supply pipe installed in the heating chamber is installed in a zig-zag shape inside the partition wall.

According to the pyrolysis energy recovery device of the waste using the waste incineration heat according to the present invention, after separating the waste of incineration and the waste of pyrolysis, the waste of pyrolysis is pyrolyzed using heat generated in the process of burning the waste of incineration. By making it possible to use the energy efficiently.

In addition, according to the pyrolysis energy recovery apparatus for waste products using waste incineration heat according to the present invention, the combustion gas generated in the process of incineration of the waste to be incinerated can be burned to a degree close to complete combustion to reduce environmental pollution. It has an effect.

In addition, according to the pyrolysis energy recovery apparatus of the waste using the waste incineration heat according to the present invention there is an advantage that the hot water can be produced by the heat generated in the process of waste incineration.

Hereinafter, the configuration and operation of a pyrolysis energy recovery apparatus for waste products using waste incineration heat according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

2 is a front sectional configuration diagram of a pyrolysis energy recovery apparatus for waste products using waste incineration heat according to an embodiment of the present invention, Figure 3 is a cross-sectional configuration of a pyrolysis energy recovery apparatus for waste products using waste incineration heat according to an embodiment of the present invention 4 is a side cross-sectional view of a pyrolysis energy recovery apparatus for waste products using waste incineration heat according to an embodiment of the present invention.

Reference numeral 100 denoted in the drawings indicates a pyrolysis energy recovery apparatus for waste products using waste incineration heat constructed according to an embodiment of the present invention, and describes a pyrolysis energy recovery apparatus for waste products using waste incineration heat according to an embodiment of the present invention. For convenience, it may be abbreviated as a pyrolysis energy recovery device.

The pyrolysis energy recovery apparatus 100 according to the embodiment of the present invention is partitioned into a heating chamber 220 and a pyrolysis chamber 230 with a heat plate 210 interposed therebetween as shown in the drawing. 220 is mainly composed of a pyrolysis furnace 200 that enables the thermal decomposition of the waste in the pyrolysis chamber 230 by the heat generated in the process of incineration of the waste.

On the other hand, in the pyrolysis furnace 200 according to an embodiment of the present invention, a waste inlet 232 is installed on the upper side of the pyrolysis chamber 230, while a rotary 234 for spreading the wastes introduced from the waste inlet 232 is evenly spread. Is installed below the waste product inlet 232.

In addition, a residue discharge screw 236 is installed on the heat plate 210 to discharge the residue generated in the process of the input waste products are pyrolyzed. And, the upper side of the pyrolysis chamber 230 is provided with a steam outlet 238 through which the discharge of steam generated in the process of pyrolysis of waste in the pyrolysis chamber 230 is installed, the steam passing through the steam outlet 238 The oil component of is configured to be extracted as a liquid oil component through a condenser and a cooler not shown in the drawings.

In addition, one side of the heating chamber 220 of the pyrolysis furnace 200 in the pyrolysis furnace 200 according to the embodiment of the present invention is heated to a temperature of a predetermined level so that the input waste can be pyrolyzed. A plurality of main burners 222 are installed at regular intervals.

In particular, in the pyrolysis energy recovery apparatus 100 according to an embodiment of the present invention, the waste incineration means including the main burner 222 is additionally installed to enable the incineration of waste in the heating chamber 220. A waste conveying screw 240 is installed across the lower portion of the heating chamber 220 as a part of the incineration means, and a waste inlet 242 is installed at one end of the side into which the waste is introduced into the waste conveying screw 240. Meanwhile, at the other end, a residual waste outlet 244 for discharging the incinerated waste residue is installed.

On the other hand, the waste introduced into the heating chamber 220 along the waste conveying screw 240 is burned by the flame of the main burner 222 while the residual waste discharged through the residual waste outlet 244 is a residual waste discharge screw. 246 is configured to be discharged to the outside.

In the pyrolysis energy recovery apparatus 100 according to an embodiment of the present invention, a combustion gas duct for discharging combustion gas generated in a process in which the main burner 222 is operated in the heating chamber 220 and a waste is incinerated ( 250 is piped as shown in the figure. That is, the combustion gas duct 250 is piped so that the combustion gas of the heating chamber 220 can flow into the lower portion of the boiler 300 which is separately installed at one side of the pyrolysis furnace 200. The combustion gas flowing along the combustion gas duct 250 is used to heat the water introduced into the boiler 300 while circulating along the flow path provided in the boiler 300.

On the other hand, in the pyrolysis energy recovery apparatus 100 according to an embodiment of the present invention the boiler for heating the water by the combustion gas and the separate water heating burner 302 generated in the heating chamber 220 of the pyrolysis furnace 200. 300 is installed. At this time, the boiler 300 is installed between the pyrolysis furnace 200 installed at a predetermined interval as shown in the figure.

The housing 310 of the boiler 300 according to the embodiment of the present invention is formed in a cylindrical shape while the combustion gas duct 250 is connected to the lower side of the housing 310. Meanwhile, a spiral flow path 320 for helical circulation is induced until the combustion gas introduced into the housing 310 through the combustion gas duct 250 is discharged to the exhaust port 312 provided at the upper portion of the housing 310. It is provided in the form of a spiral between the housing 310 and the bucket 314.

And, as shown in the drawing according to an embodiment of the present invention, two boilers 300 are installed at predetermined intervals, while each of the boilers 300 has a combustion gas duct 250 in a planar 'X' shape. Piping is installed.

In addition, the combustion gas heat exchanger 330 is installed at the rear of the exhaust port 312 of the boiler 300 to allow the combustion gas passing through the exhaust port 312 of the boiler 300 to be condensed. . When passing through the heat exchanger 330, the condensed combustion gas flows along a separate transfer line 340.

On the other hand, the water supply pipe 350 is installed in the pipe so that the water is supplied to the boiler 300 according to an embodiment of the present invention is a predetermined section is located inside the heating chamber 220 as shown in the figure . That is, a predetermined section of the water supply pipe 350 is installed to pass through the inside of the heating chamber 220 to be supplied to the boiler 300 by heat generated in the process of incineration of waste in the heating chamber 220. The water is configured to be heated to a predetermined level of temperature.

In the pyrolysis energy recovery apparatus 100 according to an embodiment of the present invention, the heating chamber 220 is provided with a plurality of waste conveying screws 240 in two sets, and between two waste conveying screws 240 in one set. A partition 260 is provided to guide the flame direction of the main burner 222.

As described above, the water supply pipe 350 in the section in which the partition wall 260 is located among the sections of the water supply pipe 350 in which the piping is installed in the heating chamber 220 is installed in a zig-zag shape inside the partition wall 260. do.

Meanwhile, as shown in the figure, a final combustor 400 is installed between the boiler 300 and the boiler 300 so that the combustion gas is combusted close to the complete combustion. An auxiliary burner 410 is installed on one side of the final combustor 400 in order to smoothly burn the combustion gas condensed in the final combustor 400 described above.

Hereinafter, the operating state of the pyrolysis energy recovery apparatus 100 according to an embodiment of the present invention will be described briefly.

In the pyrolysis furnace 200 in the pyrolysis energy recovery apparatus 100 according to an embodiment of the present invention, incineration of waste and pyrolysis of renewable wastes are performed at the same time. That is, incineration of the waste which can be incinerated is performed in the heating chamber 220 of the pyrolysis furnace 200, and the pyrolysis chamber is formed by the high temperature heat according to the waste incineration in the heating chamber 220 and the operation of the main burner 222. In 230, pyrolysis of plastic waste is performed.

Waste products such as plastics injected into the waste product inlet 232 are pyrolyzed in the pyrolysis chamber 230 of the pyrolysis furnace 200 to be in the form of steam. The pyrolysis gas in the steam state is discharged through the steam outlet 238. After passing through a condenser and a cooler, the phase changes into a liquid extract. And the waste residue after the pyrolysis is discharged to the outside of the pyrolysis chamber 230 through the residue discharge screw 236.

The waste introduced into the heating chamber 220 along the waste conveying screw 240 is incinerated by the operation of the main burner 222, and the waste residue which is not completely incinerated remains by the residual waste discharge screw 246. It is discharged to the outside through the waste outlet 244.

The combustion gas generated in the heating chamber 220 flows to the boiler 300 along the combustion gas duct 250. As such, the combustion gas of the heating chamber 220 flowing toward the boiler 300 is used to warm water in the boiler 300. That is, the combustion gas flowing into the boiler 300 along the combustion gas duct 250 flows upward while turning along the spiral flow path 320 provided inside the boiler 300 to heat the water tank 314 installed in the boiler 300. Done.

On the other hand, the water in the water supply pipe 350 installed to pass through the heating chamber 220 is heated in the process of incineration of waste in the heating chamber 220. The heated water is supplied to the boiler 300 side, the temperature of the combustion gas passing through the spiral flow path 320 of the boiler 300 and further heated by the water heating burner 302, where hot water is needed. Supply will be.

Combustion gas discharged through the exhaust port 312 of the boiler 300 is condensed while passing through the heat exchanger 330, the condensed combustion gas is supplied to the final combustor 400 side along the transfer line 340 and then assisted The burner 410 burns close to complete combustion. Therefore, only the minimum pollution component is discharged from the exhaust port of the final combustor 400.

In the pyrolysis energy recovery apparatus 100 configured as described above, not only the useful oil component can be extracted through pyrolysis of renewable plastic wastes, but also heat generated in the incineration process of wastes to be incinerated is required for pyrolysis of wastes. By acting as a circle, efficient energy utilization is possible.

In addition, by using the heat generated during the incineration of the waste to make hot water as well as to reduce the pollution by burning the combustion gas generated during the incineration of the waste to a level close to complete combustion.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

1 is a view for explaining a conventional technology.

Figure 2 is a front sectional configuration diagram of a pyrolysis energy recovery apparatus of the waste using waste incineration heat according to an embodiment of the present invention.

Figure 3 is a cross-sectional configuration diagram of a pyrolysis energy recovery device of the waste using waste incineration heat according to an embodiment of the present invention.

Figure 4 is a side cross-sectional view of a pyrolysis energy recovery device of the waste using waste incineration heat according to an embodiment of the present invention.

[Description of Code for Major Parts of Drawing]

100. Pyrolysis energy recovery device 200. Pyrolysis furnace

210. Heat Plate 220. Heating Chamber

222. Main burner 230. Pyrolysis chamber

232. Waste inlet 236. Residue discharge screw

240. Garbage transfer screw 242. Garbage slot

244. Residual waste discharge 246. Residual waste discharge screw

250. Combustion gas ducts 260. Bulkheads

300. Boiler 310. Housing

312.Air vents 314. Bucket

320. Spiral Euro 330. Heat Exchanger

250. Water supply pipe 400. Final burner

Claims (5)

The interior of the pyrolysis furnace is divided into a heating chamber and a pyrolysis chamber with a heat plate interposed therebetween, while a waste inlet is installed at the upper side of the pyrolysis chamber while a rotary is installed in the pyrolysis chamber so that the wastes introduced from the waste inlet can be spread evenly. And a residue discharge screw for discharging the residue is installed on the heat plate, and the waste introduced into the pyrolysis chamber is thermally decomposed by the heating of the main burner installed in the heating chamber, so that useful oil components are extracted. In the pyrolysis energy recovery device for waste products, A waste conveying screw is installed across the lower portion of the heating chamber, but a waste inlet is installed at one end of the waste conveying screw on the side where the waste is introduced, while a residue of the burned waste may flow out at one end of the waste conveying screw. Refuse incineration means is installed so that the residual waste discharge port is installed so that the waste introduced by the main burner installed in the heating chamber is incinerated; Combustion gas ducts are installed on the side of the heating chamber so that the combustion gas generated in the process of incineration of waste by the main burner installed in the heating chamber is discharged to the outside; A cylindrical housing is installed on the side of the pyrolysis furnace, and the end of the combustion gas duct is connected to the lower side of the housing, while the combustion gas introduced through the combustion gas duct is discharged to the exhaust port provided in the upper part of the housing. A boiler provided with a water heating burner installed at one side of the housing such that a spiral flow path is installed therein so as to induce circulation of the water, and a heated water is heated through a water supply pipe installed inside the heating chamber; And A combustion gas heat exchanger installed behind the exhaust port of the boiler to condense the combustion gas passing through the exhaust port of the boiler; Pyrolysis energy recovery device of the waste using the waste incineration heat, characterized in that configured to include. According to claim 1, One side of the combustion gas heat exchanger to burn the condensed combustion gas through the combustion gas heat exchanger close to complete combustion is further provided with a final combustor for burning the combustion gas condensed by the auxiliary burner A pyrolysis energy recovery apparatus for waste products using waste incineration heat. According to claim 1, wherein the pyrolysis furnace is installed on each side of the boiler, respectively, the combustion gas duct piped between the boiler and the pyrolysis furnace is used in the waste incineration heat, characterized in that the pipe in the 'X' shape on the plane. Pyrolysis energy recovery device for waste products. According to any one of claims 1 to 3, wherein the heating chamber is provided with a plurality of two sets of waste transport screw, but between the two set of waste transport screw for inducing the flame direction of the main burner A pyrolysis energy recovery apparatus for waste products using waste incineration heat, characterized in that a partition is installed at a predetermined length. The pyrolysis energy of waste products using waste incineration heat according to claim 4, wherein the water supply pipe in the section in which the partition wall is located among the sections of the water supply pipe in which the piping is installed in the heating chamber is installed in a zig-zag shape inside the partition wall. Recovery device.

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