CS213422B1 - Intersection of the permeation pipe system through the membrane wall - Google Patents

Description

This design node must avoid the occurrence of additional stresses, must reliably absorb significant thermal dilatations and, in addition, must be gas-tight throughout its service life.

In the penetration according to the invention, at the point of passage of each transfer bundle tube in the respective flag portion of the bellows adjacent and welded circumferentially fixed to the wall tubes and flag strips from the outside of the membrane wall, a bellows opening is formed for it is substantially coaxial with respect to said wall opening, the penetration tube being sealed in the bellows opening.

213 422

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to the penetration of a conduit through a membrane wall of a system, in particular a transfer tube bundle extending from an outer space through a membrane wall into the inner space of a steam boiler.

In interconnecting and thermally stressed pipe systems located in the immediate vicinity and inside the combustion chamber of the steam boiler, the problem of solving gas-tight penetration of small dimensions, reliably retaining relatively large thermal dilatations and eliminating the additional stresses in passing pipes is a major problem. The tubular membrane bundle connects the outside of the collecting chamber with the heat exchange tubes located inside the combustion chamber. The tubular membrane wall here is formed by wall tubes, between which the strips are fixed longitudinally, which are also commonly fixed known as pennants or flag moldings.

In the second known penetration, the penetration tube is provided at its passage through an opening in the membrane wall flag with a through protective sleeve provided on its surface, the protective sleeve being again circumferentially welded in the opening of the respective flag.

In a third known penetration embodiment, each transfer tube bundle passing through openings in the same membrane wall flag is enclosed in a trough-shaped metal box located outside the combustion chamber. The openings in its bottom are circumferentially welded with the penetration tubes and the edges of their walls are then welded along its entire periphery to the wall tubes and flags of the membrane wall.

In a fourth known embodiment of the penetration, the interior of its similarly formed box is filled with a sealant of refractory material, so that the weld joints do not need to be gas-tight here.

The advantage of the first known embodiment of the penetration is the perfect gas-tightness of the joints, a great disadvantage is the rigidity of the clamping, which increases the risk of a high additional stress on the membrane wall and the conduit, especially at smaller lengths of the outer portions of the penetration tubes. Due to the considerable thermal expansion between the collecting chamber and the membrane wall, this beer design requires a large length of the outer part of the conduit and is therefore relatively expensive. Due to the complexity of the shapes of the investigated components of the penetration, the computational check of stress in the stressed area of penetration at the membrane wall is also very problematic.

In the second known embodiment of the penetration, a very good gas-tightness of the joints is also ensured, the penetration tube is also somewhat protected from the sudden thermal transition into the combustion chamber and from the sharp notch effects of the weld joint at the point of passage through the membrane wall. This is because the parts that are not directly stressed by internal overpressure are welded together. Also in this second embodiment, the high drawback stiffness with all the above-mentioned adverse consequences is a big disadvantage.

In the third known embodiment, the gas-tightness is also guaranteed, but the stiffness of this penetration depends mainly on the design of the protective box, which always has an increased stiffness near the fronts, which results in excessive additional stresses in some conduit tubes. parts of the conduit tubes can be produced with respect to compensation over longer lengths and hence also tracks.

The advantage of the fourth known embodiment is satisfactory compliance, but a considerable disadvantage is the unbearable gradual reduction of the gas-tightness of the combustion chamber.

A significant part of the above-mentioned existing penetration solutions of the pipe systems is eliminated by the penetration embodiment according to the invention. SUMMARY OF THE INVENTION A wall space is formed in the respective diaphragm wall flag rail at the point of passage of each conduit bundle tube and in a flat part of the bellows adjacent to and welded to the wall tubes and at least one flag rail from the outside For the passage and fastening of the transfer tube, a bellows opening is provided which is substantially coaxial with respect to said wall opening, the transfer tube being sealed in the bellows opening.

The penetration of the invention is very compliant so that it allows to reduce additional stresses in both penetrating pipe systems and ensures a constant tightness even with all their relative thermal expansion position changes, while still allowing the distance of the collecting chamber to the membrane wall to be reduced. As a result of the shortening of this distance and thus the length of the conduit tube system, considerable investment and material savings are made. The substantially flexible plastic hinged arrangement of the two penetrating pipe systems practically makes it impossible to transfer undesirable moments and thus facilitates, after judging and calculation of the stress pattern, the determination of optimal mutual dimensions.

Examples of embodiments of the invention are shown in the accompanying drawings.

Fig. 2 is the overall layout of the penetration in a side view, Fig. 3 and 4 show the first embodiment of the penetration in detail *

6 is a third embodiment of the penetration in detailed plan axial section, and FIGS. 7 and 8 are the fourth and fifth embodiments of the penetration again in detailed plan sections.

In the overall disposition of the penetration according to FIGS. 1 and 2, the collecting chamber 1 is interconnected through the conduits 2 of the conduit tube system, consisting of three conduits, interconnected, with heat exchange pipes, not shown, located in the combustion chamber of the boiler.

Due to the need for maximum compensation of thermal dilatations, the collecting chamber 1 is positioned at a distance h relative to the membrane wall and the outer ends of the conduits 2 are bent before being connected to the collecting chamber 1.

Each of the four membrane walls surrounding the combustion chamber of the boiler is formed, according to FIGS. 1, 2 and 3, by a series of vertical wall tubes 2 ^θ between intermediate and welded joints 2 with continuously fixed flag strips 4. Each of the respective flag strips 4 is formed £ circular wall openings for the free passage prostupových pipe 2. on each triplicate prostupových tubes 2 extending through the wall openings 2 ^{in the} same flyout sheet 4 according to FIGS. 3 and 4 from the outer side of the membrane wall by its central flat portion strung tight bellows 6, both its peripheral parts enclose the outer curves of the wall tubes 2 · Bellows 6 i

213 422 is fastened by welded joints 6 provided in its flat part along the circumference of each bellows opening. The bellows 6 is then secured to the wall tubes and flag strips 4 of the membrane wall by a welded joint 8 over its entire circumference. The slats 4 are approximately equal to the length difference w of the waveguide edges of the bellows 6 and the outer radii r of the wall tubes 2 ' The permeability of the pipes 2 in the bellows 6 and the considerable flexibility of the bellows 6 guarantee a stable gas-tightness as well as a high compensating ability of the first penetration.

In the second embodiment of the penetration shown in Fig. 5, sleeve-like protective sleeves 10 are threaded on its penetration tubes 2, which partially compensate for the sharp temperature interface and notch effects of the mounting weld joints 6 in the walls of the penetration tubes 2 already sufficiently stressed by internal pressure. In this second penetration embodiment, the advantageous possibility of using a bellows 6 with tapered edge wave portions, which are welded directly to the wall tubes 2, is also indicated.

The integral protective sleeves 10 which are inserted on the penetration tubes 2 are mounted and sealed on them by means of welded joints (not shown).

In the third embodiment of the penetration shown in FIG. 6, longitudinally cut or split protective sleeves 10 are used to reduce the sharp thermal interface in the walls of the conduit 2, whereby their longitudinal edges and their alignment on the conduit 2 are secured by welding. The clearance in the receptacles of the protective sleeves 10 on the penetration tubes 2 and thus the gas tightness of these receptacles are ensured by residual tensile stresses in the weld joints. In this penetration embodiment, the penetration tubes 2 are arranged in pairs in each penetration bundle. In the membrane wall, therefore, the spacing of these adjacent penetration tubes 2 is substantially equal to the spacing of their wall tubes 2, ^{and the} bellows 6 here consists of two flat parts and three wave parts, so that it is somewhat wider.

According to the fourth embodiment of the penetration shown in FIG. 7, the penetration tubes 2 are provided with inner and outer protective sleeves 10 which are partly offset by the sharp temperature interface and the notch effects of the assembly welds 6.

In the fifth embodiment of the penetration shown in FIG. 8, the sleeves 10 threaded and welded on the outside of the membrane wall 2 are fitted at their outer ends. Due to the free fit of the outer shoulder ends of the penetration tubes, they are appropriately enlarged as the wall openings 2 in the flag 4 as well as bellows holes in the flat portions of the bellows 6 for the welded joints.

Claims (7)

1. Penetration of a conduit through a membrane wall, in particular a conduit 213 422, extending from the outer space through the diaphragm wall to the inner space of the steam boiler, characterized in that a wall opening (5) is formed in the respective diaphragm wall flag rail (4) at the point of passage of each transfer tube (2). in the flat part of the bellows (6) adjacent and welded (8) circumferentially fixed to the wall tubes (3) and to at least one flag strip (4) from the outside of the membrane wall, it is formed for passing and fastening the penetration tube (2) A wafer opening substantially coaxial with respect to said wall opening (5), the penetration pipe (2) being sealed in the bellows opening. Penetration according to claim 1, characterized in that the ratio of the distance (v) between the diaphragm strip flag (4) and the flat part of the bellows (6) at the point of attachment of the penetration tube (2) to the distance (w) between the flag strip (4). 4) and the waveguide part of the bellows (6) is in the range! from 0.1 to 1.00. Penetration according to claim 1, characterized in that a weld joint (7) is provided at the point of attachment of the penetration tube (2) in the bellows opening of the bellows (6). 4. Penetration according to item 1, characterized by: A screening sleeve (10) mounted on the inner side and / or in the wall opening (5) of the flag casting (4) is fastened to the penetration tube (2). Penetration according to claim 3, characterized in that the weld joint (7) is provided between the bellows (6) and the protective sleeve (10) mounted on the penetration tube (2) and extending into the bellows opening. Penetration according to Claims 1 and 4, characterized in that the protective sleeve (10) is circumferentially interrupted by at least one separating joint. Penetration according to Claims 1 and 4, characterized in that the protective sleeve (10) is provided at the point of passage through the wall opening (5).