KR20030041714A - Screw of sulfur separator in desulfurization equipments - Google Patents

Abstract

PURPOSE: Provided is a sulfur separator pipe perforation apparatus capable of perforating a drain pipe of a sulfur separator without stopping operation of the sulfur separator. CONSTITUTION: The apparatus comprises an upper and a lower cylinder bases(206b, 206a) of disk shape installed above a cover(110) of a sulfur separator(10) and separated from each other by a certain distance, an operating cylinder(100) installed on the upper cylinder base(106a) and having a rod(103) penetrating the upper cylinder base, a motor support installed between the upper and lower cylinder bases(206b,206a) and being linearly movable in a vertical direction by being coupled to the rod, a motor(200) fixed to the motor support and having a motor shaft(201) penetrating the motor support, a steam pipe fixed to the motor shaft(201) and installed near above a drain pipe of the sulfur separator(333), and a drill coupled to a lower end of the steam pipe.

Description

Sulfur separator penetrating device in desulfurization equipment {SCREW OF SULFUR SEPARATOR IN DESULFURIZATION EQUIPMENTS}

The present invention relates to a sulfur separator penetrating device in a desulfurization system that can penetrate with steam by crushing carbon, which is a sulfur impurity, accumulated at a lower end of a sulfur separator in a desulfurization facility in a chemical plant.

Normally, as shown in FIG. 1, the acid gas 3, which has been gasified through a distillation process in an ammonia distillation unit, is introduced together with the air 2 in the catalytic reactor 1 so that the high temperature in the catalytic reactor 1 is increased. (About 1000 to 1200 degrees) is decomposed into nitrogen and hydrogen, hydrogen sulfide is cooled while passing through the sulfur cooler (4) to recover the liquid sulfur (8), a portion of the unrecovered liquid sulfur (8) is a catalytic reactor (5) and the liquid sulfur 8 recovered after being recovered from the sulfur separator 10 through the sulfur condenser 7 is transferred to a sulfur storage tank (not shown) and shipped through the vehicle.

However, as shown in FIG. 2, carbon 13, which is sulfur impurity, accumulates at the lower end of the sulfur separator 10 to close the pipe 15 to frequently stop the operation of the ammonia distillation unit and the desulfurization unit. In addition, when the lower end of the sulfur separator 10 is closed by the carbon 13, the liquid sulfur 8 is gradually accumulated in the sulfur separator 10, flows through the connecting pipe 17 flows into the post process to the subsequent process Interfering with the work produced a problem of stopping the whole facility.

In addition, in order to penetrate the interior of the sulfur separator 10, the worker opens the cover 11 and then removes the internal filter 12, and the lower drain pipe (not shown) of the sulfur separator 10 is removed. Since the penetrating work should be carried out using a tool such as a steel pipe after removal, there is a problem that a risk of safety accidents exists and work is difficult and cumbersome.

The present invention has been made to solve the above-mentioned conventional problems, and when the drain line of the sulfur separator is closed by sulfur impurity carbon, the operation of the equipment is continuously performed without removing the cover of the sulfur separator and the internal filter. It is an object of the present invention to provide a sulfur separator penetrating device in a desulfurization facility that can perform a penetrating operation while reducing the downtime and the risk of a safety accident.

1 is a schematic process diagram of a general desulfurization plant,

2 is a partially cutaway perspective view of a sulfur separator according to the prior art,

Figure 3 is a perspective view of the installation state of the device of the present invention,

4 is a cross-sectional view of main parts of the present invention device;

5 is an enlarged view of a portion 'A' of FIG. 4;

6 is an enlarged view of a portion 'B' of FIG. 4.

Explanation of symbols on the main parts of the drawings

10: sulfur separator 100: working cylinder

105: motor support 106: guide post

107: limit switch 200: motor

204: steam pipe 207: drill

208 steam injection hole

The above object of the present invention is provided with a disk-shaped upper and lower cylinder base of the same structure provided on the cover side of the sulfur separator and spaced apart from each other; An operating cylinder installed on an upper surface of the upper cylinder base such that the rod is disposed therethrough; A motor support connected to the rod to be movable up and down and provided between the upper and lower cylinder bases; A motor fixed to the motor support and having a motor shaft disposed therethrough; A steam pipe fixed to the motor shaft and disposed above the drain pipe of the sulfur separator and having a flow path for guiding the supplied steam; It is achieved by providing a sulfur separator penetrating device in the desulfurization facility, characterized in that it comprises a drill connected in communication with the bottom of the steam pipe.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is a perspective view of the installation state of the device of the present invention, Figure 3 is an external perspective view of the device of the present invention.

2 to 3, a lower cylinder base 206a is provided at the top of the sulfur separator cover 110, and an upper cylinder base 206b is provided at a distance above the lower cylinder base 206a. The upper surface of the upper cylinder base 206b is provided with an operation cylinder 100, and the upper and lower cylinder bases 206a and b are fixed to each other by the support 108.

The rod 103 of the operation cylinder 100 is connected to the rod connecting rod 104, and the rod connecting rod 104 is coupled to the motor support 105.

The motor 200 is seated and fixed to the upper surface of the motor support 105, and the motor 200 is installed to move upward and downward with the motor support 105. Moving grooves 105a and b are perforated by penetrating the upper and lower ends of the ends 105, and guide posts 106 are inserted into the moving grooves 105a and b.

The guide post 106 is fixed in the upper surface of the lower cylinder base 206a, and smoothly guides the motor support 105 to which the motor 200 is fixed.

In addition, a limit switch 107 is provided on one side of the inner surface of the guide post 106 to limit the falling distance of the motor 200.

The motor shaft 201, which is a rotation shaft of the motor 200, is connected to the steam pipe 204.

As shown in FIG. 5, a connection portion “A” between the motor shaft 201 and the steam pipe 204 is provided with fixing grooves 212a and 212b formed at both sides of the shaft side connecting portion 212. The sizes of the 212a and 212b may be such that the connection keys 213a and 213b of the steam pipe side connection portion 213 can be inserted therein.

The connection portion 213 of the steam pipe side has connection keys 213a and 213b formed at both sides thereof, and a steam charging hole 214 is formed at the center to allow steam (nitrogen) to enter, and a steam pipe 204 is mounted at the bottom thereof. do.

The shaft side connection part 212 and the steam pipe side connection part 213 are fixed by the connection covers 211a and 211b and fastened by bolts 216.

Bearings 215 are fitted to the connection covers 211a and 211b to smoothly rotate the motor shaft 201 and the steam pipe 204.

The flexible pipe 203 of FIGS. 3 and 4 is mounted to a predetermined portion of the steam pipe side connecting cover 211b, and a steam valve 202 is mounted to the front end of the flexible pipe 203.

In addition, the mechanical seal 205 is provided at the central portion of the lower cylinder base 206a through which the steam pipe 204 is penetrated.

The steam pipe 204 is connected to the drill 207, as shown in Figure 6 showing 'B' of Figure 4 in detail and the shortest edge 210 of the drill 207 is not closed to the bottom of the sulfur separator 10 It is installed to a length that is not, it is provided to have a size smaller than the inner diameter of the drain pipe (333).

An intermediate blade tip 209 is provided at an adjacent position of the shortest blade tip 210, and the intermediate blade tip 209 is sharply formed to penetrate solid sulfur and carbon well, and steam or nitrogen is formed inside the drill 207. A plurality of steam ejection holes 208 are formed to be able to enter.

Therefore, stuck carbon can be easily removed while preventing sulfur from adhering to the drill 207, and the drain pipe 333 of the sulfur separator can be purged.

In FIG. 3, an inlet pressure gauge 113 capable of checking and transmitting the pressure of the site is installed at the inlet of the sulfur separator 10, and an outlet pressure gauge 114 having the same function is provided at the outlet to provide a differential pressure gauge 301. And pressure transmission, the differential pressure gauge 301 is connected to a computer 300 for monitoring and managing the process.

The present invention configured as described above will be described below with respect to the operation.

When carbon, which is sulfur impurity, accumulates at the lower end of the sulfur separator 10, the drain pipe 333 is closed, and the liquid sulfur gradually accumulates inside the sulfur separator 10, and the pressure gauges 113 and 114 of the inlet and outlet portions of the sulfur separator 10 are disposed. When the measured pressure is transmitted to the differential pressure gauge 301 and the value is more than a predetermined value, the steam valve 202 is opened by the command of the computer 300 and steam enters the steam charging hole 214 and the steam pipe 204 The steam is blown into the steam jet hole 208 of the drill 207 and the motor 200 is started.

The drill 207 connected to the motor shaft 201 is rotated by the driving of the motor 200, and the connection covers 211a and 211b are fixed without turning.

After the motor 200 is started, the operation cylinder 100 is operated so that the motor 200 and the drill 207 are lowered along the guide post 106 in the vertical direction, and the carbon is fixed to the lower portion of the sulfur separator 10. It will penetrate sulfur.

When lowered by a predetermined distance or more, the limit switch 107 and the motor support 105 are in contact with each other to automatically return the operation cylinder 100 and the motor 200 to the initial position.

At the same time, the motor 200 is stopped and the steam valve 202 is also locked.

As described in detail above, according to the present invention, the carbon impurity attached to the lower end of the sulfur separator is crushed to prevent the closing of the sulfur separator, thereby maintaining a normal operating state without interruption of the desulfurization equipment, and thus the quality of the COG. And can maximize the purification efficiency, and also to prevent the leakage of dangerous goods can ensure the safety of workers.

Claims (4)

Disc-shaped upper and lower cylinder bases 206a and 206b of the same structure which are provided on the cover 110 of the sulfur separator 10 and spaced apart from each other; An operating cylinder (100) installed on an upper surface of the upper cylinder base (206a) so that the rod (103) is disposed therethrough; A motor support 105 connected to the rod 103 so as to be movable up and down and provided between the upper and lower cylinder bases 206a and 206b; A motor 200 fixed to the motor support 105 and having a motor shaft 201 disposed therethrough; A steam pipe 204 fixed to the motor shaft 201 and disposed above the drain pipe 333 of the sulfur separator 10 and having a flow path for guiding the supplied steam; Sulfur separator penetrating device in the desulfurization facility, characterized in that it comprises a drill 207 is installed in communication with the lower end of the steam pipe (204). The method of claim 1, wherein the motor support 105 is disposed through both ends and is guided up and down by the guide post 106 installed in the upper surface of the lower cylinder base (206a) with an appropriate width. Sulfur separator penetrating device in a desulfurization facility. The desulfurization system according to claim 2, wherein the guide post 106 is provided with a limit switch 107 for generating a signal which interferes with the motor support 105 and returns it to an initial position at a part of its length. Sulfur separator penetrating device. [2] The sulfur separator penetrating device according to claim 1, wherein the drill (207) has a plurality of steam ejection holes (208) formed on an outer circumferential surface thereof to communicate with an internal steam flow path of the steam pipe (204).