KR101846513B1 - Multi-tube type organic sludge pyrolysis device for possible heat recovery and recycling - Google Patents

Abstract

The present invention relates to a multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat. In a process of transferring the organic sludge through the multiple tubes, the heat is transferred to the organic sludge supplied for pyrolysis from the pyrolyzed organic sludge to preliminarily heat the sludge so that the organic sludge can be pyrolyzed with a small amount of thermal energy, and the time of heating the organic sludge in a limited section or region can be controlled, thereby enhancing pyrolysis efficiency of the organic sludge.

Description

TECHNICAL FIELD [0001] The present invention relates to a multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat,

The present invention relates to an organic sludge pyrolysis apparatus, and more particularly, it relates to an apparatus for pyrolysis of an organic material sludge by heat transfer from the organic sludge pyrolyzed in the process of transferring the organic sludge through multiple tubes, A multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat, which can pyrolyze organic sludge with low thermal energy and increase the efficiency of pyrolysis treatment of organic sludge by controlling the heating time of the organic sludge in a limited region or region .

Generally, leaving organic sludge, which is a waste such as sewage sludge, food waste or livestock wastewater, in a natural state causes environmental pollution such as leachate, odor and pest generation.

These organic sludge can be used as an energy source sufficiently and can be used as a useful energy source such as pyrolysis and gasification for stable treatment rather than simply disposal.

The pyrolysis process of the organic sludge during the process is to supply high temperature thermal energy to the organic sludge. At this time, the organic sludge immediately after pyrolysis process has heat energy of more than 3000 kcal per 1 kg.

It is economically very useful to recover or utilize thermal energy from the organic sludge that has undergone pyrolysis, and many techniques have been developed for this purpose, but the efficiency is low.

In addition, the organic sludge is composed of a high molecular compound, such as carbohydrate, protein or lipid, and is decomposed into glucose, amino acid, fatty acid and the like when it is pyrolyzed by heating at 200 ° C or more together with water.

Various methods have been devised for treating organic sludge using the principle of decomposing the organic sludge by heat. However, not only a lot of heat energy is required in the process of heating to high temperature, but also it is required to continuously operate It is difficult to construct an apparatus for treating organic sludge.

Particularly, in the conventional organic sludge disposal apparatus, since the sludge at room temperature is directly heated to 200 ° C or more in order to pyrolyze the organic sludge, heat energy required for the temperature rise is excessively required.

The conventional organic sludge treatment apparatus described above has a low energy efficiency due to a low energy of solids recovered compared to the input thermal energy, so that the method of treating organic sludge, which is waste, is not economical.

In order to increase the pyrolysis efficiency of the organic sludge through the conventional organic sludge disposal apparatus, it is inevitable to heat the organic sludge to an excessively high temperature or to increase the heating time of the organic sludge. As described above, There is a problem in that excessive heat energy required for the temperature rise is caused to occur.

In order to solve this problem, there has been proposed a method in which the organic sludge is heated or the region is enlarged to increase the heating time of the organic sludge. However, such a method naturally leads to the enlargement of the organic sludge disposal apparatus. There is a problem in that it is difficult to manufacture the processing apparatus and also raises the unit price of the processing apparatus, and the installation space of the processing apparatus must be considerably secured.

Therefore, a heat exchanger or the like capable of performing heat exchange so that the energy used for heating can be reused in the organic sludge disposal apparatus is separately required. An apparatus for treating the organic sludge, It is required to develop an organic sludge treatment device capable of increasing the efficiency of pyrolysis treatment of organic sludge by controlling the heating time of the organic sludge even in a relatively short section or a limited area.

Korean Registered Patent No. 10-1500630 (published on Mar. 19, 2015)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a method and apparatus for continuously and continuously thermally decomposing and re- The present invention provides a multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat to reduce consumption.

It is another object of the present invention to provide a method and apparatus for opening and closing a flow passage of an organic material sludge in a zone where the organic material sludge is heated and controlling the time of heating the organic material sludge in a relatively short section or a limited area, The present invention provides a multi-tubular organic sludge pyrolyzing apparatus capable of recovering and reusing heat to increase the efficiency of pyrolysis treatment.

In order to accomplish the above object, a multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat according to the present invention comprises a first pipe connected to a reservoir of an organic sludge and connected to a reservoir of an organic sludge, ; A first partitioning part extending from the first pipe to the second pipe and being divided into a plurality of pipes and surrounding the second pipe; A second divider extending from the second tube to the first tube and divided into a plurality of tubes and surrounding the first tube; A heating unit having a heater surrounding the first tube and the second tube in the interval between the first and second divided portions; And a discharge unit connected to the first and second divided units to discharge the organic sludge, wherein the organic sludge in the storage tank is discharged through the first pipe, the second pipe and the heating unit, And the organic sludge flowing through the first pipe and the second pipe receives heat energy from the organic sludge flowing through the second and the first divided parts, respectively.

The heating section may include: a first heating tube in a section between the first tube and the first divided section; A second heating tube in a section between the second tube and the second division; And a heater installed along the first heating tube and the second heating tube.

The first heating pipe and the second heating pipe are adjacent to each other and can be offset from each other.

Wherein the first heating pipe and the second heating pipe are respectively connected to the first and second division portions and extend from the first pipe and the second pipe portion, respectively, and a valve unit for opening and closing the flow passage of the organic sludge More than one can be installed.

The heating unit may further include a controller to which a temperature sensor is attached and controls driving of the valve unit in connection with the valve unit and the temperature sensor.

A heat insulating member may be further provided to cover at least any one of the outside of the first divided portion and the second divided portion and the outside of the first heating pipe and the second heating pipe including the heater.

The space between the outer surface of the first tube and the second divided portion and the space between the outer surface of the second tube and the first divided portion may be filled with thermal conductive material along the longitudinal direction.

According to the structure of the present invention, the organic sludge is transported through the multiple pipes and heat is transferred to the sludge supplied during the transportation for discharging the pyrolyzed organic sludge, thereby reusing the heat recovered from the discharged organic sludge By heating the supplied organic sludge, it is possible to reduce the supply amount of heat energy, thereby reducing the supply cost of heat energy.

Then, the organic sludge pumped in the storage tank flows and is heated and then branched. The pumped organic sludge is heated by the heat recovered from the organic sludge pyrolyzed before being heated by the heater, thereby improving the time for pyrolyzing the organic sludge The efficiency of pyrolysis treatment of the organic sludge can be shortened and the energy efficiency of the organic sludge treatment apparatus can be maximized by thermally decomposing the organic sludge in a short time with a small thermal energy.

Further, by opening and closing the organic sludge flow passage in the heating section through one or more valve units provided in the heating section, it is possible to control the time for heating the organic sludge in a relatively short section or a limited range, It is possible to reduce the size of the organic sludge disposal apparatus and reduce the installation space of the processing apparatus in a state where the pyrolysis treatment efficiency of the organic material sludge is raised.

In this way, the pyrolysis efficiency of the organic sludge is improved, and the pyrolysis of the organic sludge is accomplished according to the pyrolysis efficiency of the organic sludge. In addition, the transporting pressure of the organic sludge accumulated by blocking or closing the organic sludge flow passage for increasing the heating time of the organic sludge It is possible to effectively transfer the organic sludge due to the increase of the fluidity of the organic sludge.

Further, it is possible to manually control the driving of the valve unit, and also to automatically control the driving of the valve unit through the control unit connected to the valve unit. When such a control unit receives a signal from the temperature sensor mounted on the heating unit So that the organic sludge can be heated to the optimum temperature already set in the heating section and then transferred and discharged.

1 to 4 are sectional views schematically showing a multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat according to the present invention.
5 is a cross-sectional view schematically illustrating the arrangement of a first pipe, a second pipe, a second pipe and a first pipe of a multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The detailed description of the technical structures in the same or similar categories will be omitted. .

In the present invention, heat is transferred from a pyrolysed organic sludge to a pyrolysis organic sludge in a process of transferring the organic sludge through a multiple pipe, and the pyrolysis is performed to preliminarily heat the pyrolyzed organic sludge so that the organic sludge can be thermally decomposed And more particularly, to a multi-tubular organic sludge pyrolysis apparatus capable of recovering and reusing heat, which can increase the pyrolysis efficiency of the organic sludge by controlling the heating time of the organic sludge in a limited section or region.

1 to 5, the structure of the present invention includes a reservoir S, a first pipe 10, a second pipe 20, a first partition 14, a second partition 20, (24), a heating unit (30), and a discharge unit (40).

1 to 4, the first pipe 10 of the present invention may have a circular or rectangular shape in its longitudinal section and may be connected to a storage tank S, So that the organic sludge fed from the sludge S is fed.

At this time, the first pipe 10 is connected to one of the storage tanks S so that the organic sludge supplied thereto can be transferred to the other side, and the second pipe 10 and the one storage tanks S The organic sludge may be supplied to the discharging unit 40, which will be described later. The organic sludge may be selectively applied considering the installation environment of the organic sludge disposal apparatus, the convenience of manufacturing, and the like.

The first tube 10 is divided into a plurality of tubes and constitutes a first divided portion 14 extended from the first tube 10 to the other side to closely contact the second tube 20 to be described later Wrap it.

Here, the first divided portion 14 is connected to the discharge portion 40, which will be described later, so that the pyrolyzed organic sludge flows to the other side to be discharged through the discharge portion 40, and one discharge portion 40 And a second flow dividing section 24, which will be described later, to be discharged through the flow path of the organic sludge, which can be selectively applied in consideration of the installation environment of the organic sludge disposal apparatus and the ease of fabrication.

The first partitioning part 14 is made of the heat insulating material itself or the heat insulating member I is provided on the outer surface of the first partitioning part 14 so that the heat of the organic sludge pyrolyzed after passing through the heating part 30, So that the inside of the first divided portion 14 is kept warm.

In addition, the heat conductive material F may be filled along the longitudinal direction at a gap between the first divided portion 14 and the outer surface of the second tube 20, which will be described later. In the manufacturing process, the first divided portion 14 The heat conduction efficiency between the first divisional part 14 and the second conduit 20 is improved by providing the thermally conductive material F at the interval between the first divisional part 14 and the second conduit 20, To keep it.

1 to 4, the second tube 20 is a hollow tube whose inside is hollow and whose length, diameter or shape is the same as or similar to that of the first tube 10 described above, And may be formed in a circular or rectangular shape in its longitudinal section. The organic sludge supplied from the storage tank S is connected to the storage tank S to form a flow path for transporting the organic sludge.

At this time, the second pipe 20 is connected to the other one of the storage tanks S, and the organic sludge supplied thereto can be transferred to one side. The first pipe 10 and the one storage tank S are connected together It is preferable that the organic sludge to be connected and supplied at the same time is transported to the discharging unit 40 to be described later so as to form the transport direction of the organic sludge in the direction opposite to the first pipe 10 described above.

The second tube 20 is divided into a plurality of tubes and constitutes a second divided portion 24 extending to one side of the second tube 10 to closely contact the first tube 20 Wrap it.

Here, the second partitioning part 14 is connected to the discharge part 40, which one side is to be described later, so that the pyrolyzed organic sludge flows to one side and is discharged through the discharge part 40, and one discharge part 40 The first sludge disposal unit 14 may be connected to the first sludge disposal unit 14 to discharge the organic sludge through the flow path of the organic sludge, which can be selectively applied in consideration of the installation environment of the organic sludge disposal apparatus and the manufacturing convenience.

The second partitioning part 24 is made of a heat insulating material or the heat insulating member I is provided on the outer surface of the second partitioning part 24 so that the heat of the organic sludge pyrolyzed after passing through the heating part 30, So that the inside of the second divided portion 24 is kept warm.

In addition, a space between the second division 24 and the outer surface of the first tube 10 may be filled with a thermally conductive material F along the longitudinal direction, The heat conduction efficiency between the second divisional part 24 and the first tube 10 can be improved through the provision of the heat conductive material F at the interval between the outer circumferential surface of the first tube 10 and the outer surface of the first tube 10, To keep it.

The arrangement of the first pipe 10, the second pipe 24, the second pipe 20 and the first pipe 14 is the same as that of the first pipe 10 and the second pipe 24, The first partition 10 and the second pipe 20 which are closely contacted with each other and the organic sludge flowing in the second partitioning part 24 and the first partitioning part 14, It can be applied variously to transfer heat to the organic sludge flowing in the first pipe 10 and the second pipe 20.

1 to 4, the heating section 30 includes a first tube 10 and a heater 22 surrounding the second tube 10 in the interval between the first division section 14 and the second division section 24, (31) to heat the organic sludge flowing from the reservoir (S) toward the discharge portion (40) described later.

The heating unit 30 can control the transfer of the organic sludge through the valve unit 50 to be described later. The first pipe 10, the first pipe 14 and the second pipe 20 And the second partitioning part 24 and is capable of maintaining the continuous transfer of the organic sludge. The plurality of heaters 31 may be connected to the heating part 30, The sludge is heated and then transferred to the first divided portion 14 and the second divided portion 24.

The heating unit 30 is connected to the first heating pipe 32 in the section between the first pipe 10 and the first partitioning unit 14 and between the second heating pipe 32 and the second partitioning unit 24, And a heater 31 installed along the second heating pipe 33 and the first heating pipe 32 and the second heating pipe 33.

Here, the first heating pipe 32 and the second heating pipe 33 are arranged such that each one of the first heating pipe 32 and the second heating pipe 33 is disposed adjacent to and shifted from the first pipe 10 or the second pipe 20 by bending or warping And are connected to the first divided portion 14 and the second divided portion 24, respectively,

The heater 31 can be installed on the outer surface or the inner surface of the heating unit 30 and the organic sludge flowing in the first heating pipe 32 and the second heating pipe 33 can be heated And it can be disposed separately in the first heating pipe 32 and the second heating pipe 33. In addition,

In addition, the heater 31 can selectively apply various heating members such as an electric heater, a radiator, a heater rod, a boiler, or a hot air fan depending on the installation environment.

For example, in the heater 31 described above, heat of 200 ° C or more is transferred to the organic sludge, and the temperature of the organic sludge transferred to the first divided portion 14 and the second divided portion 24 is also 200 ° C or more, .

The organic sludge transferred from the first pipe 10 and the second pipe 20 passes through the first heating pipe 32 and the second heating pipe 33 through the heating unit 30, So that pyrolysis can be achieved.

The organic sludge pyrolyzed through the transfer and heating processes is transferred to the inside of the first partitioning part 14 and the second partitioning part 24 through the first heating pipe 32 and the second heating pipe 33 .

The first heating pipe 32 and the second heating pipe 33 of the heating unit 30 are provided with at least one valve unit 50. The first heating pipe 32 and the second heating pipe 33, 2 The temperature sensor T is mounted on the rear side of the valve unit 50 based on the flow direction of the organic sludge flowing in the heating pipe 33.

The temperature sensor T measures the temperature of the inside of the first heating pipe 32 or the second heating pipe 33 and measures the temperature of the organic sludge flowing in the inside of the first heating pipe 32 or the second heating pipe 33. The control unit C And the temperature signal is inputted to the control unit C so that the control unit C can control the valve unit 50 to be described later.

The heating unit 30 includes a heating member I disposed on the outside of the heating unit 30 so as to surround both the heater 31 and the first heating pipe 32 and the second heating pipe 33, By keeping the whole of the heat insulation, the heated temperature of the transported organic sludge can be maintained more effectively.

In addition, the heating unit 30 can be configured such that the first heating pipe 32 and the second heating pipe 33 are simultaneously deformed in a shape such as "U" The flow direction of the organic sludge flowing inside the heating tube 32 and the first partitioning part 14 and the inside of the second tube 20, the second heating tube 33 and the second partitioning part 24 are opposite to each other And the direction in which the organic sludge is supplied from the storage tank S or discharged toward the discharge unit 40 may be the same direction and may be selected in consideration of the installation environment of the organic sludge disposal apparatus, Can be applied.

1 to 4, the discharge portion 40 is formed in a shape similar to that of the first tube 10 and the second tube 20, and is connected to the other side of the first divided portion 14 and the second divided portion 14, And the organic sludge pyrolyzed through the heating unit 30 is discharged to the outside through a connection to one side of the sludge tank 24.

The discharge section 40 may be separately connected to the first division section 14 and the second division section 24 as described above and one discharge section 40 may be connected to the first division section 14 ) And the second partitioning part 24, which can be selectively applied in consideration of the installation environment of the organic sludge disposal apparatus and the ease of fabrication.

The discharge portion 40 is provided with a relief valve 41 at an inner upper portion thereof to discharge the pyrolyzed organic sludge when the pressure in the first divided portion 14 and the second divided portion 24 reaches a set pressure .

The organic sludge pyrolyzed as it passes through the heating unit 30 and transferred to the inside of the first divided unit 14 and the second divided unit 24 is heated by the first divided unit 14 and the second divided unit 24, Is continuously conveyed along the longitudinal direction in the two-split section (24) and discharged to the outside through the discharge section (40).

The pyrolyzed organic sludge passing through the first divided portion 14 and the second divided portion 24 passes through the corresponding second pipe 20 and the first pipe 10 in the conveying direction of the sludge conveyed in the first pipe 10 As shown in Fig.

Here, when the pyrolyzed organic sludge flows in the first divided portion 14 and the second divided portion 24, heat is transferred to the second pipe 20 and the first pipe 10, The heat of the pyrolysed organic sludge is recovered from the second pipe 20 and the first pipe 10 and the organic sludge is discharged through the second pipe 20 and the inside of the first pipe 10, As shown in FIG.

Since the already heated organic sludge is heated by passing through the heating unit 30 by heating the organic sludge to be supplied for the pyrolysis treatment in the feeding process before heating, ) Can significantly reduce the amount of heat energy to be supplied.

For example, the organic sludge fed from the storage tank S and passed through the first pipe 10 and the second pipe 20 is heated to 200 ° C through the first heating pipe 32 and the second heating pipe 33.

The organic sludge having the heat of 200 ° C is conveyed along the first divided portion 14 and the second divided portion 24 and then discharged to the outside through the discharge portion 40. At this time, And is subjected to heat exchange with the organic sludge passing through the second pipe 20 and the first pipe 10.

Here, the organic sludge passing through the second pipe 20 and the first pipe 10 undergoes heat exchange with the pyrolyzed organic sludge, passes through the second pipe 20 and the first pipe 10, 33 and the first heating pipe 32, it is conveyed to the heating unit 30 in a state of being heated to 150 DEG C or higher.

Accordingly, since the organic sludge already heated to 150 ° C or more can be heated only by 50 ° C through the heating unit 30, the amount of heat energy to be supplied from the heater 31 can be reduced, The cost can be reduced.

Further, the time for heating the organic sludge to an appropriate temperature by heating the organic sludge supplied from the storage tank S by reusing the heat recovered from the organic sludge pyrolyzed before passing through the heating unit 30, The time for heating the organic sludge to the temperature for pyrolysis treatment can be shortened and the pyrolysis treatment efficiency can be increased.

The first reservoir 10, the second reservoir 20, the first reservoir 14, the second reservoir 24, the heating unit 30, and the discharge unit 40, The valve unit 50 which can be included in the present invention together with the valve unit 50 is provided in the heating unit 30 and opens and closes the flow path of the organic sludge in the heating unit 30, One or more of the first heating pipe 32 and the second heating pipe 33 are selectively provided.

The valve unit 50 is disposed inside the first heating pipe 32 or the second heating pipe 33 as a normal butterfly valve or the like to open and close the organic sludge flow passage .

The valve unit 50 constructed as described above is connected to a control unit C connected to the temperature sensor T mounted on the rear side of the valve unit 50 with reference to the flow direction of the organic sludge in the heating unit 30, So that the control unit C can control the valve unit 50 through the temperature signal inputted from the temperature sensor T to the control unit C so that the temperature of the limited heating unit 30 The organic sludge may be heated to an optimum temperature already set within the section or area and then transferred to the first and second divided sections 14 and 24.

The temperature of the inside of the first heating pipe 32 or the second heating pipe 33 measured by the temperature sensor T in the process of transferring and heating the organic sludge through the valve unit 50 may be optimized The control unit C having received the measured temperature signal blocks or closes the flow passage of the organic sludge by driving the valve unit 50 so that the organic sludge is supplied to the inside of the heating unit 30 for a predetermined time So that the pyrolysis efficiency of the organic sludge can be maximized.

By allowing the opening and closing of the organic sludge flow passage in the heating section 30, it is possible to control the heating time of the organic sludge even in a relatively short section or a limited area, thereby improving the pyrolysis efficiency of the organic sludge, It is possible to reduce the size of the organic material processing apparatus and to reduce the installation space of the processing apparatus in a state where the efficiency is increased.

In addition, not only the pyrolysis of the organic sludge is well performed according to the pyrolysis efficiency of the organic sludge, but also the organic matter sludge accumulated due to the closing of the organic sludge flow passage for increasing the heating time of the organic sludge, Due to the increased fluidity of the sludge, the transfer of the organic sludge can also be achieved effectively.

Of course, when the temperature inside the first heating pipe 32 or the second heating pipe 33 measured by the temperature sensor T is measured at an optimal temperature already set, the valve unit 50 is not driven, The thermally decomposed organic sludge can be transferred to the first dividing section 14 or the second dividing section 24 and can also be automatically controlled through the control section C connected to the temperature sensor T. [

The present invention is not limited to the above-described embodiments. Anything having substantially the same constitution as the technical idea described in the claims of the present invention and achieving the same operational effect is included in the technical scope of the present invention.

10: first tube 14: first division
20: second branch 24: second division installment
30: heating section 31: heater
32: first heating tube 33: second heating tube
40: discharge part 41: relief valve
50: valve unit C: control unit
F: thermally conductive material I: insulating member
S: Storage tank T: Temperature sensor

Claims (7)

A first pipe (10) and a second pipe (20) connected to a storage tank (S) of the organic sludge and forming a flow path of the organic sludge, respectively;
A first partition (14) extending from the first pipe (10) toward the second pipe (20) and divided into a plurality of pipes and surrounding the second pipe (20);
A second partition (24) extending from the second pipe (20) toward the first pipe (10) and divided into a plurality of pipes and surrounding the first pipe (10);
A heating unit 30 having a heater 31 surrounding the first tube 10 and the second tube 20 in the interval between the first and second divided portions 14 and 24; And
And a discharge unit 40 connected to the first and second division units 14 and 24 to discharge organic sludge,
The organic sludge in the storage tank S flows to the discharge unit 40 via the first pipe 10, the second pipe 20 and the heating unit 30,
The organic sludge flowing through the first pipe 10 and the second pipe 20 receives heat energy from the organic sludge flowing through the second divided portion 24 and the first divided portion 14, ,
The heating unit 30 includes a first heating pipe 32 in a section between the first pipe 10 and the first partition 14; And a second heating pipe (33) between the second pipe (20) and the second partition (24), wherein the heater (31) is connected to the first heating pipe (32) (33)
Characterized in that the first heating pipe (32) and the second heating pipe (33) are disposed adjacent to each other so as to be displaced from each other, whereby heat can be recovered and reused. delete delete The method according to claim 1,
The first heating pipe (32) and the second heating pipe (33)
A valve unit extending from the first pipe 10 and the second pipe 20 and connected to the first and second divided parts 14 and 24 for opening and closing the flow path of the organic sludge, 50) is installed at the bottom of the multi-tubular organic sludge pyrolysis apparatus. 5. The method of claim 4,
The heating unit 30 is equipped with a temperature sensor T,
Further comprising a control unit (C) connected to the valve unit (50) and the temperature sensor (T) to control the operation of the valve unit (50). The multi-tubular organic sludge pyrolysis Device. The method according to claim 1,
At least one of the outside of the first partitioning part 14 and the second partitioning part 24 and the outside of the first heating pipe 32 and the second heating pipe 33 including the heater 31 And a heat insulating member (I) covering the heat insulating member (I). The method according to claim 1,
The distance between the outer surface of the first tube 10 and the second divided portion 24 and the distance between the outer surface of the second tube 20 and the first divided portion 24 are respectively along the lengthwise direction of the heat conductive material F). The apparatus for pyrolysis of multi-tubular organic sludge is capable of recovering and reusing heat.

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