BG62667B1 - Device for the connection of pipelines for purged gas from a piece of equipment for removing sulphur from flue gases of a coal-type fuels firing electric power plant to a water cooling tower with natural counterflow - Google Patents

Abstract

The invention relates to a device where investment costs are reduced, contact of the gases entering the cooling tower and its lining and the mixture between the gas and the steam in it are avoided, and no chimney is required. The flow of scrubbed gas is discharged centrally of the cooling tower, encircled by the vapours. Ducts (1) for scrubbed gas from a connection flange (3) of the equipment (2) for the elimination of sulphur from flue gases directly and rectalinearly, with or without previously made intermediate supports, are driven across the lining (4) of tower (5). The discharge of gases from vertical outlet pipe connections (7) is above the plane of water dispersion (11), i.e. at least to the level of connection flange (3) of the equipment for the elimination of sulphur from flow gases. The diverting devices (6) have vertical outlet pipe connections (7) and guiding blades (8) and are positioned by means of pipe connections (7) with an angle of setting in such a way that the projection of the outgoing gas streams coming out of pipe connections (7) vertically and in the middle, fall into the rotationally-symmetrical axis of the cooling tower (5) in the zone of an upper ring-like supporting beam (9). The length of a pipe connection (7) corresponds to at least 1.5 times the diameter of the duct (1) for scrubber gas. 2 claims, 4 figures

Description

Field of application

The invention relates to a device for connecting purified gas pipelines from a flue gas desulphurisation plant of a fossil fuel power plant to a counter-flow water cooling tower, avoiding a chimney construction.

BACKGROUND OF THE INVENTION

It is known to fully connect the purified flue gases for complete mixing in cooling towers. The purification gas pipeline, after its exit from the flue gas desulphurisation plant, is deflected through a hole vertically and immediately thereafter horizontally. The purification gas pipeline is repeatedly supported and inserted directly above the water spray plane in the cooling tower.

The disadvantage of this design is the high cost of the required or necessary supports for the gas pipelines. The available two bumps below 90 ° are associated with high investment costs and cause high pressure losses, thereby increasing the consumption of electricity to drive the suction fans. Increased wear is caused. The gases are introduced into the lower area of the cooling tower and have contact with the walls of the cooling tower, due to the mixing effect. This leads to increased surface loading through chemical influences and requires additional precautions.

Another device is known in which the flue gases are introduced through a horizontal pipeline into the cooling tower directly into the upper half of the heat exchanger, through the water dispenser and through a drop separator (DE - PS 3709553).

The proposed solution does not detail the design of the flue gas intake into the cooling tower. It is further unclear whether this applies to the purified or untreated flue gas.

The direct introduction of flue gases into the gas environment of the cooling tower is done by various structural devices, which are usually provided with differently shaped outlets for better mixing of the flue gases with the gas environment in the cooling tower (DE - OS 3321961, DE- A 3433707, DE-A 3327931).

This mixing effect is achieved by openings at the upper peak point which are located almost over the entire length of the pipelines inside the cooling tower and which protrude from the discharge chamber. Mixing can, due to the chemical aggressiveness of the clean gas, lead to short or long term damage to the concrete or parts of the reinforcement, so investment costs may be required to maintain the construction.

The introduction of flue gases over the heat exchange elements into the cooling tower is known over a diffuser-like cylinder with adjustable vertical protection (DE - PS 3518787).

The purpose of this patent is to better blend the introduced gas stream with the rising flow of cooling air to avoid contact of the inner liner of the cooling tower with the aggressive substances. By adjusting the cross section of the cylinder, it is possible to better adjust to different production protection states.

Better blending of the two streams in a known manner leads to an increase in the aggressiveness of the mixture, which at risk of contact with the inner walls. The solution has a gas installation in the cooling tower.

In this connection, a chimney system for the removal of gas flows from thermal power plants as well as from nuclear power plants is known in the cooling towers (US-C 3 488 960). In that solution, a stainless steel chimney was installed centrally in the cooling tower. This chimney is enclosed and is carried by a ventilation tower made of high quality concrete or masonry.

The purpose of this structure is to achieve mixing of the exhaust gas stream with the smoke from the tower. Damage to the cooling tower cladding is not taken into account. The solution requires additional investment costs for the tower needed and the various devices needed for it.

The gas pipeline is introduced into the cooling tower directly above the water spray plane. The gas pipelines are repeatedly closed. The patent description cannot eliminate the presence of a sulfur removal facility.

Technical nature

The technical problem to be solved by the invention is to reduce investment costs, to avoid contact of the purged gases introduced into the cooling tower with the walls, and to avoid mixing of the purified gases and the gas environment of the cooling tower. On the contrary, the jet of clean gas must necessarily be drawn to the central part of the cooling tower, surrounded by the gas environment of the cooling tower.

This technical problem according to the invention has been solved by the creation of a device for connecting purified gas pipelines from a flue gas removal plant of a fossil fuel power plant to a counter-flow water cooling tower of the following construction. A deflection device is provided which is positioned visibly above the water spray plane, has vertical outlet nozzles and guide vanes and is located in the center of the cross section of the cooling tower. In particular, two purification gas pipelines are connected to a connecting flange of the flue gas desulphurisation device. The two pipelines, directly and perpendicularly, with or without intermediate supports, are passed through the cooling tower shell. Through the vertical outlet nozzles of the respective deflection devices, the pipelines are arranged with an angle of alignment so that the extension of the outgoing nozzles vertically and centrally outgoing gas jets falls into the rotationally symmetric axis of the cooling tower at the height of the upper annular beams. The angle of establishment a depends on:

- the distance s between the two purification gas pipelines at the center of the horizontal axis at the theoretical deflection point;

- mounting mounting height h, relative to the horizontal axis at the theoretical deflection point;

- the total height H of the cooling tower;

- displacement of a of the gas pipelines;

the layout scheme of the whole installation, and

- on the selected slope (about 1%) between the horizontal gas pipelines.

The length of one vertical outlet nozzle corresponds to at least 1.5 times the diameter of the purification gas pipeline, with the gas outlet being at least at the height of the axis of the connecting flange of the flue gas desulphurisation device.

The invention has the following advantages: investment costs are greatly reduced due to the avoidance of breakage and intermediate supports, reducing production losses (very low suction power required), reducing the contact gases with the shell wall of the cooling tower. completely prevented by this type of input, due to the negligible loss of pressure in the purified gas pipelines, the cost of starting the suction fan is reduced, increasing the flow rate. the outlet of the purified gas exerts a positive effect on the load on the liner. Subsequent investment costs for any necessary repair of the cooling tower shell may be delayed or not made at all, an increase in the exit level influences external damage, since the kinetic energy (impulse) of the purified gas is used more efficiently. good.

Description of the attached figures

The invention is illustrated by an exemplary application shown in the accompanying drawings, of which:

Figure 1 is a sectional view of a cross-sectional view;

Figure 2 is a sectional view of the cooling tower;

Figure 3 is a cross-sectional view device;

Figure 4 is a view of the vertical outlet fitting.

Example of implementation

The two purge gas pipelines 1 extend into the upper region of the flue gas removal plant 2 from the connecting flange and are introduced directly into the cooling tower 5, straight, without deviations and intermediate supports (Fig. 1).

Clean gas pipelines 1 do not have any supports between the flue gas removal plant 2 and the cooling tower 5. The entry of the axis of the pipeline 1 into the enclosure 4 of the cooling tower 5 lies at a height of about 40 m, and thus is located far above the water spray plane 11, which is located at a height of about 13 m with an upper edge for catching the droplets.

In the cooling tower 5, the purified gas pipelines 1 are supported by supports 10, whereby the load absorption may be different. The cleaned flue gas enters through the diversion devices 6 in the center of the cooling tower 5.

The deflection devices 6 have guide vanes 8, which cause the direction of the purified gas to change to 90 ° and are equipped with vertical outlet nozzles 7 (Fig. 4). The vertical outlet nozzles 7 are arranged at an angle of alignment such that the extension of one outlet nozzle 7 vertically and in the middle of the outlet gas stream falls into the rotationally symmetrical axis of the cooling tower 5 in the area of the upper annular beam 9 (Fig. 1 and 3).

In this way, the stream of the purified gas is centrally discharged and is surrounded by the gas medium of the cooling tower 5 without contact with the shell 4 of the cooling tower 5. There is no mixing between the jet of the purified gas and the gas medium of the cooling tower 5.

The angle of establishment a depends on:

- the distance s between the two purifying gas pipelines 1 relative to the center of the horizontal axis at the theoretical deflection point;

- mounting mounting height h, relative to the horizontal axis at the theoretical deflection point;

- the total height H of the cooling tower

5;

- displacement a of the gas pipelines 1;

the layout scheme of the whole installation, and

- on the selected slope (about 1%) between the horizontal gas pipelines 1.

List of tags used:

1. Purification gas pipeline.

2. A device for the removal of sulfur from flue gases.

3. Connecting flange.

4. Cooling tower shell.

5. Cooling tower.

6. Deviation device.

7. Vertical outlet nozzles.

8. Guide vanes.

9. Upper timber ring.

10. Props.

11. Water dispersion plane.

Claims (2)

Claims 1. A device for connecting purified gas pipelines from a flue gas desulphurisation plant of a fossil fuel-fired power plant to a natural-flow water cooling tower having a deflection device positioned visibly above the water spray plane vertical outlet nozzle and guide vanes and is located in the center of the cross section of the cooling tower, characterized in that two pipelines (1) for the purified gas are connected to a connecting flange (3) of the equipment (2). the removal of sulfur from the flue gases, both directly and in a straight line, with or without pre-made intermediate supports, are passed through the shell (4) of the cooling tower (5), by means of vertical outlets (7) of the respective deflection devices (6). with the angle of establishment a such that the extension of the outgoing nozzles (7) of the vertically and centrally exiting gas jets falls into the rotationally symmetrical axis of the cooling tower (5) at the height of the upper annular beam (9), at which the angle of establishment a for ISI from: - the distance s between the two clean gas pipelines (1), relative to the center of the horizontal axis at the theoretical deflection point; - mounting mounting height h, relative to the horizontal axis at the theoretical deflection point; - the total height H of the cooling tower (5); - displacement a of the gas pipelines (1); the layout scheme of the whole installation, and - the selected slope between the horizontal pipelines (1) for the gas, and that the length of one vertical outlet nozzle (7) corresponds to at least 1.5 times the diameter of the pipeline (1) for the gas, where the gas outlet is located 5 at least at the height of the axis of the connecting flange (3) of the equipment (2) for removing sulfur from the flue gases. A construction according to claim 1, characterized in that the 10 cloning devices (6) have vertical outlets (7) and guide vanes (8).