KR101580471B1 - Upper structure of syngas condenser - Google Patents

Abstract

The present invention relates to an upper structure of a synthetic gas condenser and, more specifically, to the upper structure of a synthetic gas condenser which separately forms a cooling chamber (20), in which cooling water circulates, between an upper chamber (10) and a lower chamber (30) and arranges a plurality of condensation pipes (50) within the cooling chamber (20) to discharge synthetic gas induced into the upper chamber (10) to the lower chamber (30), wherein a hexagonal or a rectangular expanded pipe part (60) is formed at an upper end of each of the condensation pipes (50) to be tilted and a tip end of each of the expanded pipe part (60) is bound to a tip end of the expanded pipe part (60) of another adjacent condensation pipe (50) or an inner wall of the condenser (1) to separate the upper chamber (10) from the cooling chamber (20) in the condenser (1) by a tilted surface (65) of the expanded pipe part (60), thereby basically solving conventional problems that abnormal materials like tar are accumulated and fixated on the flat surface of an upper plate which has separated the upper chamber from the cooling chamber, and preventing gas inlets of the condensation pipes (50) from getting narrow or clogged due to accumulation of the tar.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a syngas condenser,

The present invention relates to an upper structure of a syngas condenser, and more particularly, to a regeneration energy production system for purifying a syngas generated as a by-product in a carbonaceous furnace producing chaff charcoal, The present invention relates to an upper structure of a syngas condenser for improving the purification efficiency of the syngas by improving the upper structure of the condenser for refining and simplifying the checking and cleaning of the condenser.

Generally, a carbonization furnace is a device for pyrolyzing a specific material at a limited oxygen supply state to a high temperature. The applicant of the present invention invented the " vertical continuous-type carbonizing carbonization plant " I have been registered.

The applicant of the present invention has been disclosed in Patent No. 0602733, entitled " Device for obtaining hot water while producing carbonized rice husk and wood vinegar, " as an invention for recovering the waste heat by burning synthesis gas generated from the carbonization furnace of the rice husk carbonization system. Particularly, as an invention for producing electric power using the syngas generated from the above-mentioned carbonization furnace, "a method of producing renewable energy using a synthesis gas byproduct of a rice husk carbonization system" and a "production apparatus of a renewable energy using a synthesis gas by- Have been registered as Patent Nos. 1281753 and 1200208, respectively.

Hereinafter, a schematic configuration of a regenerative energy production system using syngas of a carbonaceous furnace based on the applicants' conventional inventions will be described with reference to FIG.

The syngas regeneration energy production system 100 according to the related art includes a carbonization furnace 110 for pyrolyzing raw materials such as rice hulls to produce carbides, A condenser 130 for condensing and extracting the tar and the supernatant liquid from the syngas collected by the granular dusts, and a condenser 130 for extracting the tar and the supernatant from the syngas, A wet scrubbing column 140 for highly refining impurities which are highly purified from the syngas and an electrostatic precipitator 150 and an adsorption tower 160 and a generator 170 for producing electricity using the highly purified syngas, A lead-free furnace 180 and a heat exchanger 190 for use.

Reference numeral 115 denotes a carbide reservoir 115. Reference numeral 135 denotes a super fluid tank 135. Reference numeral 145 denotes a gas liquid separator 145. Reference numeral 165 denotes an adsorbent reservoir 165. Reference numeral ' Is a syngas reservoir 173, and 175 is an internal combustion engine 175.

In the meantime, in the synthesis gas regeneration energy production system 100, the main constituent is for removing impurities contained in the synthesis gas. Particularly, in the case of producing electric power by using synthesis gas, It is more important to remove tar and flyash and fine dust so as not to deteriorate or to be inoperable.

At this time, most of the tar and the supernatant contained in the syngas are removed from the condenser 130, and the fine dust not removed from the cyclone dust collector 120 is also adsorbed and removed together with the tar and the supernatant condensed in the condenser 130 A small amount of residual foreign matter not removed in the condenser 130 is removed in the subsequent high purification process. Therefore, the removal efficiency of foreign substances such as tar contained in the syngas is significantly influenced by the performance of the condenser 130.

2 and 3, in the condenser 130, a plurality of condensing tubes 131 are arranged at regular intervals, and the condensing tube 131 is arranged in the condenser 130, An upper plate 132 and a lower plate 133 are formed at the upper and lower ends of the upper plate 132 so as to correspond to the respective condensing pipes 131. At this time, 3, the upper inlet of the condensing tube 131 is narrowed or closed. As a result, the efficiency of removing the foreign substances by the condenser 130 is lowered. In addition, in the subsequent high purification process It will have an adverse effect.

Further, in order to prevent the above-mentioned incapability of condensation, it is necessary to frequently inspect and clean the inside of the condenser 130, which may result in a problem of productivity deterioration.

Registered Patent Publication No. 10-0602733 (issued on July 20, 2006) Patent Registration No. 10-1200208 (issued on September 11, 2012) Patent Registration No. 10-1281753 (Announcement of Mar. 3, 2013)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to improve the upper structure of a condenser in arranging a plurality of condensing tubes in a condenser, The present invention has been made to solve the above-described problems of the prior art, and it is an object of the present invention to improve the efficiency of removal of foreign matter by smoothly introducing and discharging the syngas by preventing the clogging of the gas inlet at the upper end of the condenser tube .

According to an aspect of the present invention, there is provided an upper structure of a syngas condenser, wherein a cooling chamber in which cooling water circulates is formed between an upper chamber and a lower chamber, and a plurality of condensation tubes are arranged in the cooling chamber A hexagonal or quadrangular expanded portion is formed at an upper end of each of the condensed tubes so that the tip of each of the expanded portions is connected to the expansion portion of the adjacent condenser tube So that the upper chamber and the cooling chamber of the condenser are partitioned by the inclined surface of the expansion pipe portion so that the plane is excluded at the upper end of the condensation pipe so that the tar is not accumulated and fixed .

Further, according to the present invention, there is further provided a joining member having a through-hole formed between the upper end of the condensing tube and the lower end of the bending portion so that a gap is not generated in the joining face of the condensing tube and the bending portion, And a maximum width of the inner circumferential surface is smaller than an inside diameter of the condensing tube, and the joining member has a first joining member formed with a through hole and attached to the lower end of the bending portion, and a ring- And the second joining members formed on the upper end of the condensing tube are joined to each other.

According to the present invention as described above, since the upper chamber and the cooling chamber of the condenser are partitioned by the inclined surfaces of the expansion portion, foreign matters such as tar are adhered and fixed to the plane of the upper plate, Can be solved fundamentally. Therefore, it is possible not only to prevent the gas inlet of the condensing tube from being stuck or closed by the droplet of tar, but also to improve the efficiency of removing foreign matter by smoothly flowing and discharging the syngas, and on the other hand, , And ultimately it is possible to economically operate a renewable energy production system using syngas.

1 is a schematic view showing an example of a conventional syngas renewable energy production system
2 is a partial perspective view showing the internal structure of a conventional syngas condenser;
3 is an enlarged cross-sectional view showing an upper structure of a conventional syngas condenser
4 is a cross-sectional perspective view showing the upper structure of the syngas condenser according to the present invention;
5 is a front view showing an upper structure of a syngas condenser according to the present invention;
6 is a partial perspective view showing a condensation tube of a syngas condenser according to the present invention;
7 is an exploded perspective view showing the expansion portion of the condensing tube in the present invention.
Fig. 8 is an enlarged cross-sectional view showing the operating state of the expansion portion in the present invention
9 is a perspective view showing another embodiment of the present invention.

Hereinafter, an upper structure of a syngas condenser according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 4 to 9. FIG.

The condenser 1 according to the present invention is divided into an upper chamber 10, a cooling chamber 20, a lower chamber 30 and a condensate reservoir 40 from the upper side thereof. And a cooling chamber 20 partitioned between the upper chamber 10 and the lower chamber 30 is provided with an inlet 21 at a lower end of the lower chamber so that cooling water can circulate through the inlet port 15, In addition, an outlet port 22 is formed at one upper end and an exhaust port 35 for discharging the introduced synthesis gas is formed in the lower chamber 30 formed in a lower part of the cooling chamber 20.

A condensate reservoir 40 for storing the tar and the supernatant condensed by the cooling of the syngas is formed at the lower side of the lower chamber 30 and a discharge valve 45 is formed at the lower end of the condensate reservoir 40.

In the cooling chamber 20, a plurality of condensing tubes 30 are provided in the upper chamber 10 to communicate the upper chamber 10 and the lower chamber 30 such that the syngas introduced into the upper chamber 10 can be discharged to the lower chamber 30. [ The synthetic gas is cooled while passing through the condensing tube 50, so that the tar and the supernatant contained in the syngas are condensed, and the condensed tar and supernatant flow through the inner surface of the condenser tube 50 The syngas having been removed from the condensate reservoir 40 is discharged to the next process through the lower chamber 30. As a result,

In particular, the upper chamber 10 and the cooling chamber 20 are separated from each other by the condenser tube 50, unlike the cooling chamber 20 and the lower chamber 30 are partitioned by the lower plate 55 formed at the lower end of the condenser tube 50. [ (60) formed to be inclined at the upper end of the opening (50). That is, the tip of the expansion tube 60 formed at the upper end of each condensing tube 50 is connected to the tip of the expansion tube 60 of another adjacent condensing tube 50 or is joined to the inner wall of the condenser 1, The upper chamber 10 and the cooling chamber 20 of the heat exchanger 1 are partitioned by the inclined surfaces 65 of the expansion portion 60. [ At this time, the expanding portion 60 is preferably formed in a hexagonal shape. However, the scope of the present invention is not limited to the hexagonal and rectangular expanding portions 60, But the present invention is not limited to the shape of the tube portion 60.

It is preferable that the inclined surface 65 of the bulging portion 60 is formed in consideration of the interval of the adjacent condensing tubes 50 within a range of 45 degrees with respect to a virtual vertical line. It is ideal to have a slope of.

A joining member 70 having a through hole 75 formed between the upper end of the condensing tube 50 and the lower end of the bending portion 60 is further formed on the joining surface of the condensing tube 50 and the bending portion 60 It is preferable that the gap is not generated and the junction of the condensing tube 50 and the bulging portion 60 is facilitated.

Specifically, the through holes 75 formed in the joining member 70 are perforated in a hexagonal shape or a square shape having the same shape as the lower end of the expansion portion 60, so that a step is formed in which the tar agglomerated in the synthesis gas can be filled And the maximum width of the inner circumferential surface of the hexagonal or square through hole 75 is smaller than the inside diameter of the condensing tube 50 so that the cooling water in the cooling chamber is not introduced into the condensing tube.

The joining member 70 includes a first joining member 70a formed with a through hole 75 and attached to the lower end of the expansion portion 60 and a second joining member 70b formed in a ring shape and attached to the upper end of the condensation tube 50 By joining the second joining members 70b to each other, it is possible to further facilitate the joining of the condensing tube 50 and the bending portion 60.

The syngas introduced into the upper chamber 10 is introduced into the lower chamber 30 through the condensation tube 50 formed in the cooling chamber 20, The syngas is cooled while passing through the condensing tube (50), so that the tar and the supernatant contained in the synthesis gas are condensed.

The condensed tar and the supernatant flow down the inner circumferential surface of the condensing tube (50) and are introduced into the condensate reservoir (40). The upper chamber 10 and the cooling chamber 20 are separated from each other by the expanded portion 60 formed at the upper end of the condensing tube 50 so that the upper surface of the upper chamber 10 and the lower surface of the cooling chamber 20 are covered by the inclined surface 65 of the expanded portion 60 The condensed tar and the supernatant flow naturally to the condensing tube 50 without being accumulated and consequently the tar is not accumulated and adhered to the top of the condensing tube 50 and further the inlet of the condensing tube 50 Stenosis or closure is avoided.

Therefore, according to the present invention, it is possible not only to prevent the gas inlet of the condensing tube 50 from being stuck or closed by the droplet of tar, but also to improve the foreign matter removal efficiency by facilitating the inflow and outflow of the syngas. Further, the check and cleaning of the condenser 1 can be simplified, which ultimately enables economical operation of a renewable energy production system using syngas.

1: condenser 10: upper chamber
20: cooling chamber 30: lower chamber
40: Condensate storage tank 50: Condenser tube
60: expansion portion 65: slope surface
70: joining member 70a: first joining member
70b: second joining member 75: through-hole

Claims (3)

A plurality of condensing tubes 50 are arranged in the cooling chamber 20 so as to partition the upper chamber 10 and the lower chamber 30 into a plurality of cooling chambers 20, (10) to be discharged to the lower chamber (30), characterized in that the upper structure of the syngas condenser comprises:
A hexagonal or square expanded portion 60 is formed obliquely at the upper end of each of the condensing tubes 50;
The front end of each of the expansion parts 60 is joined to the front end of the expansion part 60 of the adjacent other condensation tube 50 or is joined to the inner wall of the condenser 1 so that the upper chamber 10 of the condenser 1, By allowing the cooling chamber 20 to be partitioned by the inclined surface 65 of the expansion portion 60;
Characterized in that the plane is excluded at the upper end of the condensing tube (1) so that the tar is not entrained and fixed.
The method according to claim 1,
A joining member 70 having a through hole 75 formed between the upper end of the condensing tube 50 and the lower end of the bending portion 60 is further formed so that a gap is formed in the joining face of the condensing tube 50 and the bending portion 60 The through hole 75 formed in the joining member 70 is a hexagonal or rectangular perforation having the same shape as the lower end of the expanded portion 60 and the maximum width of the inner peripheral surface of the through hole 75 is the same Is smaller than the inside diameter of the condenser (50).
3. The method of claim 2,
The joining member 70 includes a first joining member 70a formed with a through hole 75 and attached to the lower end of the bending portion 60 and a second joining member 70b formed in a ring shape and attached to the upper end of the condensing tube 50 2 joining members 70b are joined to each other.

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