KR20090096447A - Method and device for removing solids deposited on the bottom of a pipe - Google Patents

Abstract

Disclosed is a method for removing solids deposited especially on a pipe bottom of a vertical waste heat boiler with the help of the cooling water that is used. The aim of the invention is to be able to generate a predetermined solid-removing flow above the pipe bottom in order to simplify the design and create an optimum cleaning effect. Said aim is achieved by a plurality of cooling bores which are arranged at an angle to the vertical line, are introduced into the pipe bottom, and generate a positive flow of the cooling water in the region of the pipe bottom surface.

Description

METHOD AND DEVICE FOR REMOVING SOLIDS DEPOSITED ON THE BOTTOM OF A PIPE

The present invention relates to a method and apparatus for removing solids that precipitate on the bottom of a pipe.

In addition to the structural specificity of vertical heat exchangers or waste heat boilers, another problem lies in removing solids that precipitate at the bottom of the pipe out of the system to prevent damage associated with deposits such as corrosion or the like.

Removal in horizontal boilers is usually done at the bottom of the connected steam drum, and in some cases with the possibility of further removal by emptying the shell of the boiler itself.

In stationary waste heat boilers, the removal is done through a joint tube near the bottom of the pipe, in a so-called fountain design, through a central removal pipe in the center of the pipe bundle near the bottom of the pipe. In a typical U-pipe bottom split, removal may be done only at the edge of the lane without pipes between the two pipe passages, rather than at the center of the boiler without damaging the entire series of pipes.

Observing the water circulation in the vertical boiler, it is clear that the flow always runs from the outside into the hot zone of the pipe bundle, where the buoyancy is greatest due to steam generation. This is the center point of the boiler in a fountain design and, for example, the surface center of gravity of the hot half in a typical U-shaped bundle design.

Regarding the damage caused by sedimentation on the top of the pipe bottom, experience has shown that the natural circulation of water is an excellent means of transport for the solids in the boiler, and in order to avoid damage the solids must be removed and discharged out of the boiler.

Another cause of damage to the boiler is the concentration of impurities in the water supplied to the boiler, which impurities occur in areas with high steam generation. Therefore, damage to the boiler is always concentrated on the hot legs of the pipe bundles, while the cold legs are not damaged. In other words, the optimum design for a vertical boiler must consider and optimize all of these factors.

It is an object of the present invention to provide optimum removal of deposits on the bottom of pipes in vertically aligned boilers.

This object is achieved, in addition to the method of the type described above, according to the present invention by a forced flow of coolant in the area of the pipe bottom surface by means of a plurality of cooling bores arranged obliquely with respect to the vertical and introduced into the pipe bottom. do.

According to the invention, a pre-determinable removal flow can result over the pipe bottom, which leads to a simplification of design and an optimum cleaning effect.

Other features and details are set forth in the dependent claims. In particular, according to the invention the forced flow is brought from the outside towards the center of the bottom of the pipe with a drain.

This approach provides a drain in the center of the pipe bottom in order to enable the release of impurities in the center of the pipe bottom, thereby making it possible to use the existing flow anyway.

In alternating field piping, it is preferable if at least two radial lanes without pipes are provided from the outside towards the center of the pipe bottom, in which case the cooling water bores are arranged at an angle in the lane. A forced flow from the outside towards the center of the pipe bottom is brought about.

Forced flow through radial lanes, from outside to inside, already results in very good results in sediment removal.

In order to realize some sort of optimization of the cleaning effect, between the heat exchanger pipes, a forced flow formed across the flow in the radial lane may occur due to the oblique coolant bores in the bottom of the pipe. That is, flow into the radial lane outside the pipe surface results from which impurities are removed out of the system through the outlet to the center of the pipe bottom.

According to another aspect of the invention, in four radial lanes without pipes, the transverse flow generated by each pipe quadrant between the heat exchanger pipes is half formed toward one adjacent lane and the other half. Is formed towards another adjacent lane.

According to another aspect of the present invention, there is provided a method according to the invention using a waste heat boiler with an inner shirt lamination having cooling water openings in the pipe bottom area and enclosing the piping area at intervals with respect to the boiler wall. Thus, the inner shirt is installed without coolant inlet openings in the region of radial lanes without pipes such that the forced flow toward the center is enhanced by the coolant inlet openings assigned to the central region of the pipe quadrant.

This measure utilizes the inflow of coolant flowing between the inner shirt and the outer wall of the vertical waste heat boiler to enhance the cleaning effect.

In order to achieve the object described in the introduction, according to the invention, the pipe bottom is in particular a pipe bottom of a vertical waste heat boiler with alternating field piping inside the inner shirt surrounding the piping at intervals relative to the boiler shell. In addition to the bores for the rising and falling pipes in the bottom of the pipe, a number of cooling bores that are inclined with respect to the vertical line are provided for the bottom of the pipe to show its excellence.

The shape of the pipe bottom is described in the dependent claims relating to the pipe bottom, whereby the center of the pipe bottom is provided with a drain for removing washed off deposits or debris.

According to the form according to the invention there is provided cooling bores in the pipe bottom for generating a forced flow of cooling means from the outside to the inside of the waste heat boiler in the region of the pipe bottom, between at least two fields of the pipe bundle. It is preferred if the lanes are provided radially aligned radially from outside to inward and which do not have rising and falling pipes.

It has been found to be suitable for the purpose that the cooling bores in the pipe bottom, assigned to rising or falling pipes, have an inclination off the vertical line, with the extension of the cooling bores into the pipe bottom plane perpendicular to the nearest radial lane. In a tubular quadrant that is aligned with and / or formed by four radial lanes, each half of the quadrant cooling bores is assigned to a neighboring radial lane.

The above-mentioned additional use of flow by natural circulation contemplates a form of the present invention by providing coolant inlet openings close to the bottom, only in the central region of each piping quadrant, in the inner shirt surrounding the rise and fall pipes.

Other features, details and advantages of the invention are set forth in the following description and drawings.

1 is a simplified cross-sectional view of a vertical waste heat boiler.

2 is a simplified partial view of the pipe bottom.

3 is a plan view of the pipe bottom with a layout diagram of horizontal bores.

FIG. 4 is a plan view of the bottom of the pipe with the implied cleaning flow viewed from the same perspective as FIG. 3.

The vertical waste heat boiler, indicated by 1 in FIG. 1, has a pipe bottom, indicated by 3 in addition to the heat exchanger pipes 2, which is fed through a horizontal bore 4 to provide a cooling bore 5. It is provided.

1 also implies that a so-called inner shirt 7 surrounding the rising and falling pipes 2 is provided at intervals with respect to the boiler outer wall 6, the inner shirt 7 being Cooling water inlet openings (8) are provided in the region of the bottom of the pipe, through which cooling water flows downward into the inner piping region in the shell space between the boiler outer wall (6) and the inner shirt (7). have.

2 shows a partial cross section of the pipe bottom 3. The pipe bottom 3 has a drain 9 in the center, through which the impurities can be washed off.

In order to generate a forced flow from the outside towards the center of the pipe bottom and therefore towards the drain opening 9, the cooling bore 5 acted through the horizontal bore 4 is in accordance with the present invention as implied in FIG. 2. As inclined at an angle with respect to the vertical line.

The plan view of FIG. 3 implies that four lanes (labeled 10 in FIG. 4) with no piping formed radially between the ascending and descending pipes are formed, and thus the piping quadrant (in FIG. 3). Is indicated by 11).

Similarly, as shown in FIG. 3, the horizontal bores in each case are arranged parallel to the neighboring lanes 10a or 10b in half of the quadrant 11, ie each half is shifted by 90 ° C. That is, in FIG. 3 one direction of the horizontal bores is labeled 4a and the other is labeled 4b.

When the oblique cooling bores are connected to these horizontal bores, that is, the cooling bores are in such a way that the inclination of the cooling bore is in each case aligned in the direction of the lane 10 which is closest and without piping. Subsequent to the horizontal bores, in each case a transverse flow (shown by the small arrow 12 in FIG. 4) occurs, in which case the flow in the radial lane 10 without piping is small. It is implied by the arrow 13.

In order to enhance the cleaning effect, coolant inlet openings 8 can be provided in the inner shirt 7 such that the coolant inlet openings act in the central region of each quadrant. This area is implied by the double arrow 14 in FIG. 4, so that an additional flow (indicated by the arrow 15 in FIG. 4) is generated by the incoming cooling water.

Of course, the embodiments of the present invention described above may be variously changed without departing from the basic idea. That is, the cooling bores surrounding the rising and falling pipes can be tilted in the manner described here and introduced into the bottom of the pipe, as well as different slopes from inside to outside so that a kind of spiral flow from outside to inside or something like this occurs. May have

Claims (12)

In the method for removing solids that settle on the pipe bottom of a vertical waste heat boiler, in particular with the used coolant, the cooling water is forced in the area of the pipe bottom surface by a plurality of cooling bores arranged obliquely with respect to the vertical and introduced to the pipe bottom. A method for removing solids that settle on the bottom of a pipe, characterized by a flow. The method of claim 1 wherein the forced flow is from the outside to the center of the bottom of the pipe with a drain. 3. The alternating current field piping according to claim 1 or 2, wherein, in the alternating current field piping, at least two radial lanes without pipes are provided from the outside toward the center of the pipe bottom, the cooling water bores arranged obliquely within the lanes. A method for removing solids deposited on the bottom of a pipe, characterized by a forced flow from the side toward the center of the bottom of the pipe. The solid which precipitates in the bottom of a pipe according to any one of the preceding claims, characterized in that between the heat exchanger pipes, oblique coolant bores in the bottom of the pipe generate a forced flow formed across the flow in the radial lane. How to remove it. The method according to any one of the preceding claims, wherein in the four radial lanes without pipes, the transverse flow generated by each pipe quadrant between the heat exchanger pipes is formed in one half of the adjacent lanes and half of the adjacent lanes. Forming a solid at the bottom of the pipe, characterized in that it is formed towards the other lane. The waste heat boiler according to any one of the preceding claims, the outer heat surrounding the piping area with respect to the boiler outer wall and having an inner shirt lamination having coolant inlet openings in the pipe bottom area, which is assigned to the central area of the piping quadrant. The inner shirt is installed without cooling water inlet openings in the region of radial lanes without pipes so that the forced flow toward the center is enhanced by the cooling water inlet openings. Way. In the pipe bottom (3) of a particularly vertical waste heat boiler with alternating field piping inside the inner shirt surrounding the piping at intervals with respect to the boiler shell, the rising and falling pipes (2) in the pipe bottom (3) are Pipe bottom characterized in that a plurality of cooling bores (5) are inclined with respect to the vertical line in addition to the bores for it. 8. Pipe bottom according to claim 7, characterized in that the center of the pipe bottom (3) is provided with a drain (9) for removing washed off deposits or debris. The cooling bores (5) in the pipe bottom (3) according to claim 7 or 8, for generating a forced flow of cooling means from the outside to the inward of the waste heat boiler (1) in the region of the pipe bottom (3). And a lane (10) between the at least two fields of the pipe bundle radially aligned from the outside to the inside and without rising and falling pipes. 10. The cooling bores 5 in the pipe bottom, which are assigned to the rising or falling pipes 2, have an inclination off the vertical line, with cooling into the pipe bottom plane. The bottom of the pipe, characterized in that the extension of the bores 5 is aligned vertically with respect to the nearest radial lane 10. The tubular quadrant 11 according to any one of the preceding claims, wherein in the tubular quadrant 11 formed by the four radial lanes 10, each half of the quadrant cooling bores 4a, 4b is connected to a neighboring radial lane 10. Pipe floor, characterized in that assigned. The internal shirt 7 surrounding the rising and falling pipes is provided with a coolant inlet opening 8 close to the bottom only in the central region 14 of each piping quadrant 11. Pipe bottom, characterized in that.

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