NL8401858A - STEAM BOILER WITH STRAIGHT PIPES IN MODULAR SYSTEM. - Google Patents

Description

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Straight pipe steam boiler in modular system.

The object of the invention is a steam pipe in a modular system with straight pipelines, which uses as heating fluid the sodium coming from a fast culture reactor, and wherein the preheating, evaporation and superheating phases are completely caused by the water.

The steam boiler in a modular system according to the invention removes the drawback of known steam boilers which have a single module, in which the failure of one or another element of the device necessarily causes the standstill of the entire device. In the device according to the invention, on the other hand, failure of an element only causes the damaged module to be exchanged and the device can continue to operate, albeit with a reduced power.

In addition, the steam boiler in the modular system with standard modules makes it possible to realize any desired installed power, in which only the required number of modules is commissioned, 20 which clearly represents a saving in the design of devices with very different power and, in especially in the construction of the modules, which are of the same design for each joint power of the device.

In the event that one of the modules forming the modular system fails, it is not only possible to continue operating the device with the other modules, albeit with reduced power, but it is also possible to replace the damaged element for a spare module, kept ready in the workplace, where the repaired wcSrdt has been carried out.

According to the invention, the following advantages are achieved: - the device remains capable of functioning even in the event of one of its parts failing; 8401858 -2- f "* • t - the damaged module can be replaced in the short term, as a spare module can be kept ready for use; - the repair of the damaged element can be done with significant cost savings in the workshop instead of run on site.

Also, per se, one of these advantages is sufficient to establish far-reaching superiority of the subject matter of the invention over a single module steam boiler.

Each single module of the steam boiler according to the invention forms an independent steam boiler.

Sodium is used as heating fluid and the modules are built according to the counter-flow principle with 15 straight pipes.

In essence, each module consists of two collectors, between which the pipe bundle extends. Outside the pipe bundle is a jacket with two lateral collars, above and below, at the level of two annular chambers for the 20 toe resp. drain of the sodium.

At the height of the mentioned collars, the pipe bundle is provided with a cylindrical boiler partition with an interruption for the passage of the sodium.

According to the invention, the individual modules, each of which, as has just been said, each forms an independent steam boiler, are bundled around a pair of reservoirs, which are opposite each other and which supply or supply the water. collection chamber for liquid sodium forming.

Each individual module is suspended by tie rods pivotally anchored at the lower ends, while the upper ends of each module are only guided to allow the free expansion of the pipe bundle and jacket. The lower sodium reservoir is suspended from fixed containers, while the upper sodium reservoir 35 is supported by springs under constant tension, so that the vertical shifts of the devices, each of which forms an independent steam boiler, are unhindered.

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The essential features of the invention are characterized by the patent claims, the subject and advantages of which are apparent from the following description of exemplary embodiments and with reference to the accompanying drawing, In the drawing:

Fig. 1 a diametrical section through a module of the steam boiler according to the invention in a modular system,

Fig. 2 a top view of a schematic representation of a steam boiler in a modular system with four modules regularly distributed around the circumference around the axis of the joint unit,

Fig. 3 a section along the line III-III of fig.

2,

Fig. 4 on a larger scale the lower end of a module with the suspension and guiding means of the module,

Fig. 5 is a side view of the detail shown in FIG. 4,

Fig. 6 shows the top end of a steam boiler module, in particular the guiding and receiving means of the top module part.

As can be seen in the drawings, each steam boiler module 10 (see Fig. 1) consists of two equal, one-piece "pipe wall with spherical caps", namely an upper complex 11 and a lower complex 12 of the same design, which serve as collection reservoirs. for the sodium primary liquid.

The pipe bundle, designated 15 in its entirety, is welded to the two opposite pipe walls 13 and 14.

A jacket 20 with an upper collar 21 and a lower collar 22 is secured to the outside of the pipe bundle 15, within which two annular chambers 23 and 24 for the toe and neck respectively. liquid sodium discharge.

Said ring chambers are bounded inside by two boiler panels 25 and 25 respectively. 26, which surround the pipe bundle, and have the same diameter as the middle part 27 of the jacket 20. The jacket part 20 is at the two ends of the pipe wall 13 and 13, respectively. 14 welded.

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The top collector 11 has a connection piece 17 for the supply of water vapor to the turbine of the device; in the same way, the lower collector is provided with a connecting piece 18 for the supply of cold water under pressure to the module of the steam boiler.

The boiler baffles 25 and 26 have openings 28 and 26 respectively. 29 / which form the connection between the annular chambers 23 and 24 and the space bounded by the boiler partitions, in which the pipe bundle is accommodated.

In addition, each collar 21, 22 of the jacket 20 has a connecting piece 31, respectively. 32, which is connected to a chamber 33 for the supply of hot sodium and resp. to absorb the sodium that has flowed through the boiler. The reservoirs 33 and 34 collectively serve for all modules distributed in regular distances along the circumference.

The cold water flows into the lower ball cap 112, and then through the connecting piece 18 and from here, through the pipe wall 14, into the pipes of the pipe bundle 15, which flows from below upwards in the phase sequence: 20 preheating, boiling, overheating.

After this, the superheated vapor flows through the tube wall 13 into the upper sphere cap 111 and from here is led through the connecting piece 17 into the pressure lines of the turbine.

The hot sodium coming from the intermediate heat exchangers, which are not separated in the drawings, is then led to the distribution chamber 33 (fig. 2), which is common to all modules.

From the distribution chamber 33, the warm sodium enters through the connecting pipe 31 into the upper part of the jacket 30 11, i.e. into the outside through the collar 21 of the jacket and inside through the upper part of the pipe bundle enveloping, upper boiler partition 25, bounded annular chamber 23.

The opening 29 allows the warm sodium which has flowed through the annular gap 32 to flow into the tube bundle 15.

The sodium flows through the entire bundle of pipes from the top to the bottom - of course on the outside of the 8401858 3 -ΐ -5- concerning pipes - and continuously gives off its heat to the water flowing from the bottom to the top.

Thanks to the opening 28 arranged in the lower boiler partition 26, the sodium exits from the tube bundle, the annular chamber 24 flows through and, via the connecting piece 32, the collection space 34 common to a whole of steam boiler modules is reached.

As just said, the use of steam boilers built from standard elements of the nature described above makes it possible, by means of the parallel connection of different elements, to obtain the necessary power.

Should a sodium-water reaction be effected in a steam boiler, it is sufficient to separate only the element in question, whereby the device can be operated with very little loss of power.

The exemplary embodiment according to Figs. 2 and 3 is a steam boiler unit built from four modules distributed regularly around the common axis of the superposed trays 33,34.

The number of modules can of course be chosen in proportion to any desired power of the device.

The reservoir 33 arranged for feeding the sodium to the four modules of the steam boilers 10 serves as the highest point of the circuit, at the same time also as an expansion vessel. This reservoir 33 lies in the center of a square, on the four corners of which the four modules connected to the reservoir 33 by means of the connecting pieces 31 are arranged.

The lower collection reservoir 34 is symmetrical with respect to the upper reservoir 33 via the connecting pieces 32 connected to the lower ends of the four steam boiler modules. In the figure, pipes that are not separated from the collection reservoir 34 branch, namely the supply lines 35 to the secondary sodium pump and the connecting line with the sodium reservoir which is also not further separated.

The advantages achieved by the invention are: 84 0 1 8 5 8

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-6- 1. With the modular system, the unit costs are lower, which makes it possible to have a spare module ready without high extra costs.

Due to the availability of a spare module 5, in the event of a module failure, repairs can be carried out in the workshop. This results in much more reliable operation than in an on-site repair and the downtimes are essentially shortened, resulting in an essential improvement of the power plant failure factor 10.

2. From a technological viewpoint, the steam boiler according to the modular system according to the invention can be realized at relatively low cost. Apart from the welding work on the pipe and pipe wall - a critical place for every steam boiler - no other part of the device requires difficult technological interventions (straight pipes, relatively low strength).

3. The compact construction achieved by the solution according to the invention (see fig. 2) is comparable with the space required by a one-module steam boiler. Construction work is therefore not more extensive than the conventional steam boiler.

4. Since a sodium-free volume is present in the distribution and collection reservoir, in the event of a sodium-water reaction in one of the modules, the pressure wave that develops thereby is damped and, consequently, the effects thereof on the sodium pipes are reduced. The equally spaced modules about the circumference of the steam boiler, as well as the two liquid sodium distribution and collection reservoirs, are secured to the support structure, which supports it as explained below, as shown in FIG. 6, each module 10 at the level of the upper collar portion 22 of the jacket 20 has two superimposed and opposite, outwardly extending consoles of equal diameter. Pivot rods 41 are provided at the end of this console 40, which are supported at their other end 42 by means of the support frame 43 of the steam boiler retaining structure. Additional brackets 44 disposed under this bracket 40 allow the bottom end of the module 10 to be held in the axial direction against fixed stops 5 supported by the support frame 46 of the structure. Further perpendicular to the support frame 46 of the structure above the mountings 45 upwardly projecting brackets 47 are provided for limiting lateral shifts of the steam boiler module with sliding shoes known per se and therefore not shown in the drawing. As can be seen in Figure 6, the top end of module 10 has a sliding shoe 50 bracket which allows free vertical shift due to heat expansion in the direction of arrow F. The fixed stops forming a single part with the support structure of the construction 15 also serve as lateral fastening means.

Of the reservoirs 33 and 34 (fig. 2), the first is supported by means of elastic construction, which is only schematically indicated in the figure, by means of the upper construction of module 10, but only 20. The second reservoir, i.e. the sodium-absorbing reservoir 34, on the other hand, is supported by fixed carriers 52, which are also only schematically indicated, by means of the supporting structure of the construction.

Numerous changes and variants can be made to the embodiments described and shown in the drawings within the scope of professional knowledge, without thereby leaving the basic idea of the invention.

8401858

Claims (8)

1. Straight-line modular steam boiler fed by a sodium primary liquid for heating, the evaporation and superheating of a water-formed secondary liquid, characterized in that a distribution reservoir is provided with the liquid sodium and below it a sodium-receiving reservoir which has already heated up, evaporated and superheated water, which are distributed at least two steam boiler modules at regular intervals along the circumference of these two superposed reservoirs and that each individual module consists of one vertical pipe bundle and two collection reservoirs, that is to say one upper and one sub-collection reservoir, which are connected by means of suitable connectors at the top of the sodium distributor and at the bottom of the sodium-receiving reservoir. 2. Steam boiler module for use in a modular steam boiler system according to claim 1, which has a vertical pipe bundle with straight pipes, which extend between two flat, horizontal pipe walls and belong to a top collector for the absorption of the sodium resp. a sub-collector for supplying the water to the pipe bundle, characterized in that the said pipe bundle is provided by a cylindrical design in its central part and provided with two cylindrical collars at both ends, at the bottom and at the top of the two pipe walls of the said collectors welded jacket is enclosed, wherein the said collars have two annular chambers for the distribution, resp. are formed for the absorption of the sodium, which are bounded on one side by the inner wall of the jacket collar and on the other side by a pair of boiler baffles, that is to say by a bottom boiler partition enclosing the pipe bundle, and of substantially equal diameter as the central portion of the jacket, and that each collar has an opening for the passage of the sodium from the corresponding annular chamber into the free space formed by the tubes of the tube bundle and vice versa. 8401858 ^ - e -z -9- Steam boiler module according to claim 2, characterized in that the collars on the jacket have connecting pieces between the annular chambers and the distribution or collection reservoir of the liquid sodium. Steam boiler module according to claims 2 and 3, characterized in that it has a console pair lower than at the level of the upper region of the lower jacket collar, with which it is pivotally suspended from the supporting structure of the module holding structure. Steam boiler module according to claim 4, characterized in that the bottom jacket collar is provided with a radially protruding console pair, which limits the vertical displacements of the bottom module, this second console pair cooperating with fixed stops showing a horizontal engagement surface. Steam boiler module according to claims 4 or 5, characterized in that radial stop surfaces are arranged in both the lower and the upper part of the module, which permit vertical shifts, but prevent horizontal shifts. Steam boiler module according to claim 1, characterized in that the upper sodium reservoir is supported by elastic compliant carriers by the upper ends of the jackets enclosing the steam boiler module. Steam boiler module according to claims 1 and 7, characterized in that the lower sodium collection reservoir is supported by fixed carriers, which are fixed in one piece with the support frame of the construction holding the steam boiler. 8401858