FI63822C - VATTENROERSPANNA FOER AONG- OCH VARMVATTENPRODUKTION - Google Patents

Description

2 63822

WATER PIPE BOILER FOR THE PRODUCTION OF STEAM AND HOT WATER - WATERPROOF BOXING FOR SAFE PRODUCTION

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The present invention relates to a water pipe boiler of the type set out in the preamble of claim 1 for producing steam and hot water. Boilers of this type have been used for several decades in both land installations and ships, and a very large number of different constructions are already known.

The first known construction of the present type of boiler has a series of vertical convection pipes arranged centrally in the water space, each located in an Erik-10 concentrically corresponding convection duct, the lower end communicating with the combustion space and the upper end with a smoke extraction opening. The surfaces of the convection pipes are then swept by the flue gases from the combustion chamber * below, and in order to achieve sufficient heat transfer it is necessary to form the convection pipes 15 of different shapes for external strips, fins or the like to conduct the flue gases against the pipes.

The passage of water inside the convection pipes takes place through openings in the wall of each convection or flue. The lower end has an inlet which communicates with the corresponding lower end of the convection tube via a connecting tube, and similarly the upper end of the channel has an outlet and this outlet communicates with the corresponding upper end of the convection tube via a connecting tube.

As a result of the equipment used, 25 of these connecting pipes form bends in the piping and this means that effective cleaning of the inside of the convection pipes is difficult. In addition to this, the construction used is complex from a manufacturing point of view and, in addition, the construction is not particularly repair- or inspection-friendly.

30 For example, the installation of convection pipes in a corresponding duct, either in connection with a building or subsequent repairs, is complicated e.g. on the grounds that the connecting pipes forming the bends in the piping must pass tightly through the walls of the duct. In addition, the inspection of heating surfaces is difficult due to the already difficult access to the convection tubes.

35 An example of this known boiler construction is known from German application publication no. 2,226,299.

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In another known boiler construction, a combustion space and a water space above and around it are also used. The combustion chamber is connected to a substantially horizontal flue or convection duct with a vertical water or convection pipe. In order to obtain a sufficiently large heating surface, the convection duct fills the entire cross-section of the boiler practically completely and, in addition, recirculation pipes must be used to ensure water recirculation. Thus, in this known boiler construction 10, there is a flow of flue gases transverse to the convection pipes, so that external fins or the like are not necessary. In addition, the arrangement used with straight convection tubes is advantageous due to both the installation of the tubes and the possibility of cleaning the interior of the tubes.

However, the described structure of the convection duct causes the boiler to be divided in principle into two parts, namely the parts above and below the convection duct. Each of these boiler parts is, especially in smaller boilers, difficult to access, e.g. during inspection and repair due to narrow dimensions, and in all circumstances they must be provided with more access points, such as manholes.

25 An example of this last described boiler construction is known from the German advertisement publication no. 1,065,857.

German patent publication 827 952 discloses another boiler construction comprising a convection duct with an angle between the lowest part of the duct parallel to the boiler axis and the upper part oblique to the boiler axis. Such an angle in the channel is in itself a complex and costly device for manufacturing, and in addition, the angle 35 can cause unfavorable thermal stresses in the channel during use.

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In addition, the angle in the convection duct causes the lower and vertical part of the duct to be displaced practically as far as the boiler wall in order to achieve the power 5 due to the oblique upper duct part. The convection duct, and in particular its vertical part, is then not free-standing and easily accessible from all sides, which means that the duct must be provided with several manholes to ensure access to all areas of the boiler interior. In addition, the angle in the convection duct makes it difficult to clean the duct, and it is necessary to provide at least one special manhole or cleaning opening with associated ducts which allow access to the interior of the convection duct. * 15 The object of the present invention is to develop a water pipe boiler of this type which is friendly to manufacture, use and repair and which has good possibilities for cleaning and inspecting the entire pressure system.

This is achieved by the features of the boiler according to the invention set out in the characterizing part-20 of claim 1.

In the arrangement used in the boiler according to the invention, with the convection pipes arranged upwards in a separate and straight convection duct running through the water space, only one Aino-25 boiler space can be reached, and full working height can be achieved in the boiler interior. and maintenance work. The arrangement used further causes the convection tubes to be easily accessible, and it will be e.g. relatively simple to clean and replace the convection tubes, which may be and are preferably straight tubes.

The good space and access possibilities also mean that the damage to the convection pipes can be repaired in a simple way temporarily, so that the damaged or damaged pipes can be easily located and closed at both ends, after which the boiler 5 63822 can be used again.

The boiler according to the invention has a natural recirculation system and a flow-through direction in the convection tubes and elsewhere in the boiler. proved to be uniform 5 to ensure good recycling and that recycling pipes are not necessary. Since the convection tubes, as they do in the most preferred embodiment, run obliquely with respect to the horizontal direction, water flows through from the lowest end of the tube towards the uppermost end.

ΙΟ Due to the simple and sensible manufacture, it follows from the invention that the convection tubes are straight and mounted to stand perpendicular to the wall of the convection channel. The cross-section of the convection channel can have different shapes, however, the cross-section of the channel is preferably rectangular, whereby the convection pipes can be installed between opposite flat wall parts, which is the simplest arrangement from a manufacturing point of view.

In order to strengthen the well-defined flow and liquid recirculation in the invention, it is expedient for the part passing through the water space of the smallest convection channel to be inclined with respect to the vertical. By tilting the convection channel vertically at the same angle as the convection tubes are preferably tilted horizontally, it can further be achieved that the diagonally horizontal convection tubes can be mounted to stand perpendicular to the wall of the channel, which is the simplest arrangement.

For the sake of simple manufacture, it is advantageous in the invention 30 if the convection channel is symmetrical with respect to the plane of symmetry of the combustion space 1 below the vertical water space 2. In this case, it is further advantageous if the burner of the combustion chamber is located in said plane of symmetry, and if the convection channel communicates with the combustion chamber through an opening 12 projecting a distance away from the bulb 63822 in the direction 63822 perpendicular to the plane AA the upper end of the rectilinear portion is projecting towards the bulb with respect to the second plane. This achieves the possibility of the simplest thermal load on the boiler as a whole and the best possible thermal economy and efficiency.

The outlet pipe of the convection channel and the mouth part at the top of the boiler can be formed in different ways. In the steam space above the water-10 space, the convection channel can be, for example, bent and led out through the side of the boiler. However, in the invention, it is advantageous if the convection channel is preferably led directly and linearly, up through the steam space, to the upper bottom of the boiler. In the boiler according to the invention, the convection channel can thus pass from the top of the combustion chamber to the top of the boiler, and the convection channel itself thus forms a stronger support between the top of the combustion chamber and the top of the boiler. As a result, the tops of both the combustion chamber and the boiler can be formed with flat end bottoms, in contrast to previously known boilers, which use only a pleated end part, which is a more expensive and complicated element from a manufacturing point of view.

According to the invention, a special and very simple drying system can be placed in the steam outlet in connection with the latter embodiment. The part of the convection channel passing through the steam space can thus be provided with at least one and preferably a number of steam outlet pipes, the other ends of which communicate with the steam outlet. With this arrangement, a substantial portion of the generated steam 30 can be directed to flow substantially horizontally over the other side of the steam space to extend to the open ends of the steam outlet pipes through which the steam leaves the steam space. When this side flow occurs, possible foaming of the water may occur in the steam, and as the steam passes through the steam removal-35 tubes, drying and slight overheating of the steam occur. Due to the ease of manufacture, it is advantageous in the invention 7 63822 if the steam extraction pipes are arranged in substantially the same direction as the convection pipes. As the steam extraction pipes run obliquely to the horizontal, the lower ends are preferably open ends through which the steam flows in, while the upper ends of the pipes are connected to the steam outlet.

The present invention will now be described in more detail with reference to an actual application example illustrated in the drawings, in which Figure 1 shows schematically a vertical and axial section of a boiler according to the invention, Figure 2 shows a vertical section along line AA in Figure 1, Figure 3 shows a horizontal section along line 15 and Figure 4 is a top plan view of the boiler of Figure 1.

The main components of the boiler embodiment of the invention shown in the drawings are a combustion chamber 1, a water chamber 2, a steam chamber 3 and a convection duct 4.

The combustion chamber 1 is preferably made as a welded plate construction comprising a cylindrical or conical combustion chamber wall 5 and a roof 6. A suitable burner frame 7 is arranged in the wall 5, which is provided for mounting the oil burner shown. The combustion chamber, as shown in Fig. 2, is masonry or cast together with a heat-insulating stone or casting mass, and a refractory layer of stone or casting mass 8 is placed on it, which is preferably anchored. The heating surface of the combustion chamber is preferably uncoated so that heat can be easily and efficiently transferred to the surrounding boiler water in the water space 2. The boiler space is delimited by the boiler wall 9, the top 10, the outside of the combustion chamber and the intermediate ring 11 between the boiler wall and the combustion chamber wall. The boiler water space 2, which is formed by the lower part of the boiler space, thus surrounds the combustion space, the wall and roof of which are effectively cooled. However, scale 8 may accumulate on the intermediate ring 11 during use, whereby the lower part of the combustion chamber wall cannot be sufficiently cooled. The lower part of the wall of this combustion chamber is therefore preferably coated on the inside with a refractory gap with a layer 8. Still, the walls of the combustion chamber may be made of pipes.

The boiler steam space 3 consists of the upper part of the boiler space and the separation surface between the water and steam spaces thus forms the upper surface of the water in the boiler space.

The flue gases rising from the combustion chamber 1 through the opening 12 to the upper part 6 of the combustion chamber and into the convection duct 4. A number of boiler or convection pipes 13 are arranged in the part passing through the water space 2 of the convection duct, arranged in adjacent rows.

In the boiler according to the invention, the convection pipes 13 are arranged to run obliquely with respect to the horizontal. This is achieved in the most preferred alternative shown in the drawing, with the convection channel being inclined with respect to the vertical. In this way, the convection tubes 13 can consist of through, similar and straight tubes mounted to stand perpendicular to the wall of the convection channel. When the convection channel, similarly to the embodiment shown, forms a rectangular cross-section, a particularly simple and technically advantageous pipe and channel arrangement is achieved.

The lower boiler tubes 13 can, if necessary, be provided with suitable conductor plates or fins for the rapid and efficient distribution of flue gases over the entire cross-sectional area of the convection duct. The boiler tubes themselves stiffen the wall of the convection duct. If necessary, specially and suitably manufactured support pipes can be installed accordingly.

The upper part of the convection duct can be closed, for example when surface ratios are required, in the steam space 3, whereby the duct can end in a smoke outlet formed in the boiler wall 9 63822. However, according to the invention, it is advantageous if the channel 4 extends upwards through the steam space 3 into the opening 14 in the upper base 10, e.g. as shown in the drawing. In this preferred solution, the convection channel 5 thus also acts as an effective stiffener between the upper part 6 of the combustion chamber and the upper bottom 10 of the boiler, which as a result can both be made flat. If necessary, suitably placed longitudinal supports 15 can also be used. In the embodiment shown in the drawing, the inclination of the convection channel and then also the convection tubes is achieved by moving the opening 12 in the upper part 6 of the combustion chamber from the boiler center plane AA away from the bulb holder 7. Similarly, the lobby 14 in the upper 15 base 10 is pulled inward by a distance b (see Figure 4) towards the bulb frame.

The convection duct 4 extends in the opening 14 conventionally up to a suitably formed smoke extraction opening 16, e.g. as shown by the broken lines in Figure 2. The smoke extraction passage 20 may be provided with a cleaning opening 17 for use in sooting the convection duct.

The boiler according to the invention may be provided with a conventional steam outlet. However, in the embodiment in which the convection channel 4 is led up through the steam-25 space 3 into the opening in the upper part of the boiler, this special arrangement causes a special steam-drying system to be placed in it in a simple manner. As shown in Figures 1 and 2, at least 1, but preferably a row of inclined steam outlet pipes 18 can thus be placed therein. Due to their simple manufacture, these pipes are suitably arranged and oriented in the same way as convection pipes 13. The uppermost end of each pipe 18 is connected to a steam outlet nozzle 20 which is guided 35 through the upper bottom 10.

This steam outlet system described above works as follows: during operation, the strongest 10 63822 overboil and a large proportion (about 75%) of steam evolution tend to occur on the left side of the boiler center, as shown in Figure 1, and steam tends to flow over the higher side. -5 to 18 ends of supply pipes. It is desired to be able to separate any water splashes in the steam as the steam passes from left to right in Figure 1, and as the steam passes through the tubes 18 it tends to cause drying and to a lesser extent superheating of the steam. However, if desired, the convection duct 10 4 can also be provided with the actual superheater, as well as the convection duct or the flue gas outlet opening 16 can be provided with a device for improving economy or an air preheater.

As can be seen from the drawing in connection with the above description, the boiler according to the invention is particularly suitable on the basis of manufacture, use and repairs. The special internal installation of the boiler according to the invention and the placement of the convection duct and boiler tubes thus contribute to the full working height in the boiler room, 20 and at the same time there is a real need for a simple male opening 21 which can be suitably positioned either

Furthermore, the boiler has good potential for internal cleaning and possibly replacement of boiler-space tubes on the basis of these easy access and good surface area ratios. In addition, the boiler according to the invention consists of a few simple-shaped components which, when adapted to the standards of the standard components 30, allow a very short manufacturing time.

Finally, the angular shape of the convection channel with its flat walls gives little chance for soot to deposit, and soot cleaning will therefore rarely be necessary. However, the cleaning of the soot can be performed in a simple manner, also on the basis of the angular shape of the convection channel, in which an effective cleaning can be performed in the up-down direction, e.g. through the cleaning opening 17.

✓ 11 63822 For this purpose, the combustion chamber can be equipped with a suitable discharge groove 22.

In a typical embodiment of the boiler according to the invention, the convection tubes 13 are inclined about 6 ° 5 with respect to the horizontal, but other inclination angles can also be used. One embodiment, shown schematically in the drawings, may be for steam production of about 2000 kg / h in normal use at a pressure of 2 8 kp / cm. Of the other typical dimensions of this embodiment, it can be mentioned that the total height is about 3000 mm with an outer diameter of the handrail wall of 1900 mm. Finally, the lowest permissible water level in the boiler space is about 400 mm below the top of the boiler, measured from the inside.

The boiler according to the invention naturally comprises separate accessories and necessary adjustments to safety devices, which are not shown in more detail in the drawing. It is possible to mention e.g. a suitably positioned supply-water inlet line, shown schematically in Figure 1, 20, with a water level controller with adjustments and alarms for at least the lowest permissible level. The control must still be able to stop combustion at too low a water level.

Although the embodiment 25 shown in the drawing is provided for oil combustion, the boiler according to the invention is not limited to this heating method. When the boiler according to the invention is used as an auxiliary boiler for a ship, it can be arranged to be heated by the exhaust gases of the ship's main engines, which only requires a redesign of the combustion chamber. Furthermore, the boiler according to the invention can be provided for heating together with oil or exhaust gases, in which case it may comprise two or more convection ducts with their associated boiler tubes. Finally, the boiler according to the invention can, of course, be equipped for the incineration of various forms of solids or the boiler can be provided with a combustion chamber specially equipped for the incineration of waste materials such as waste oil, solid 63822 waste and residential waste.

The convection channel can be varied in many ways within the scope of the invention, e.g. with respect to shape, orientation and boiler space arrangements. The duct or part of the duct passing through the water space 5 can thus be vertical and arranged centrally in the boiler space or displaced laterally with respect to the central axis or the central plane of the boiler. In embodiments where the convection passage is inclined, this also does not need to intersect the central plane of the boiler as described in connection with the drawing, although this is most preferred. In an embodiment where the water space is below. combustion chamber, its design and temperature distribution may also have an effect on the more appropriate placement and orientation of the convection channel with respect to the boiler box.

Finally, the convection tubes 13 and the steam outlet tubes 18 do not necessarily have to form rows and groups of parallel or even directed tubes, and the tubes can also have different inclinations with respect to the horizontal.

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Claims (8)

A water pipe boiler for steam and hot water production, comprising a boiler wall (9) / which defines a water space (2), and at least one convection channel (4) extending through the water space, which has horizontal or preferably inclined to the horizontal plane (13). ) And extends rectilinearly throughout the water compartment (2) and in conjunction with a flue gas outlet (14, 16) in a passage chamber (3) located above the water compartment, characterized in that the convection duct (4) is constructed such as a leather-shaped structure composed of flat wall sections and having a polygonal, preferably rectangular cross-section, and that the convection duct as a whole is freestanding and dimensioned in relation to the boiler wall (9), and directly available from the water compartment (2). Boiler according to claim 1, characterized in that the convection tubes (13) are straight and mounted perpendicular to the wall of the convection duct (4).