FI56585C - ANORDNING FOER LAEGESHAOLLNING AV FOERBAND HOS AONGGENERATORER - Google Patents

Description

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C Patent uyjnr.c-tty 11 G2 1930 (^) Patent moddelat 1 V ^ (51) Kv.lk. '/ Lnt, CI. » F 22 B 37/24 / FINLAND - FINLAND (21) P «* nttlh» k «mu * - Patenttnsölcnln | T51065 (22) Hakamitpllvl - Aiuttkntngfdai 09.0 ^ .75 (23) Start date - Giltlfhettdag 09.0U.75 (41) Become public - Bllvit offentllg -q] _q 75

National Board of Patents and Registration of the Ministry of Patents and Registration

Patent and Regulatory Applications Anaökan utlajd och utl. «Krtft« n published 31.10.79 (32) (33) (31) Requested atuolkeua — Bejird prlorltet 10.OU.7U USA (US) U59761 (71) Combustion Engineering, Inc. 1000 Prospect Hill Road, Windsor,

Connecticut, USA (72) John Mohr Shank, Jr., E. Longmeadov, Massachusetts, USA (US) (7U) Leitzinger Oy (5U) Device for Holding Reinforcement Bindings for Steam Generators and in particular to a device for keeping their reinforcing ties in their own plane without applying large bending forces to the reinforcing supports. Large steam generators usually include furnaces lined with steam perceptual tubes and supported from the top of the unit. As the unit approaches operating temperature, the furnace structure expands vertically downward as well as horizontally. Some units operate at constant pressure in the furnace, while others operate at negative furnace pressures. In both cases, measures must be taken in the event of intermittent high-pressure transfers due to smaller explosions in the furnace or pressure increases due to the start-up of the auxiliary burner. These pressures tend to change the shape of the furnace structure due to high stresses at different locations and breakage of insulation unless measures are taken to strengthen the furnace structure. For this reason, reinforcement bandages are usually used to provide the necessary additional support. These reinforcing ties are rigid structural members placed outside the furnace structure supported therefrom, thus limiting the deformation of the furnace wall. Since the furnace pressures affect all the walls of the furnace, the reinforcing bonds on the opposite walls are connected to each other by support bonds so that the reactions against one reinforcing bond 56585 are opposed to the reactions from the opposite reinforcing bonds.

The large steam generator has a vertical expansion of the order of 30 cm above the generator's own height. . In addition, there is a horizontal expansion of the furnace walls. The temperatures of the reinforcement bonds placed outside the furnace remain lower and do not expand to the same extent as the furnace walls. For this reason, it has become accepted practice to support these reinforcing ties from the furnace wall tubes or horns at different levels so that each reinforcing bond moves vertically with the furnace wall tubes to the extent that the steam generator expands vertically at the level of this particular reinforcing bond. The reinforcing bandage is horizontally attached to the furnace wall at one point and is allowed to slide relative to the furnace wall at other support points. The joint between the opposing reinforcing joints is arranged tightly next to the furnace wall so that the joint rod structure approaches the furnace wall temperature. As a result, the horizontal movement of the opposing reinforcement bonds is approximately the same as the expansion of the furnace.

The furnace wall supports these large reinforcement joints in a free-bearing manner, whereby the weight of the reinforcement joint causes a bending moment around the support. Additional forces may be applied to the reinforcing bandage, for example when used to support pipes or other members. The application of a bending moment to the support results in large forces on the support members. Such forces on the support members can interfere with or prevent the sliding effect required due to the mutual expansion between the furnace wall structure and the reinforcing bond, and can also develop a very high local bending moment and therefore cause high stresses on the furnace wall pipes.

For this reason, other members are generally arranged to receive this bending moment. Generally, a vertical member extends downward from the upper reinforcement bond to the lower reinforcement bond, leaving a few centimeters of clearance in the lower reinforcement bond. The press with the lower reinforcement bond works together with the vertical member extending from above to resist the bending moment from the upper reinforcement bond and to dissipate it at right angles to the force against the furnace wall. This is repeated from the height of the unit by arranging 3 S6S85 three or four vertical members placed between each pair of reinforcement bonds. The vertical members of the lowest positioned reinforcement bond extend upward in the same manner as downwardly from the reinforcing bond above. In this way, the bending moment from the lower reinforcement bond is dissipated into a rectangular force in the reinforcement bond plane above and vice versa.

In such an arrangement, the reinforcement bonding members must be transported over the entire height of the unit in the segment, and for this reason a generally disordered structure is formed as well as limited access from the entire height of the unit. This also requires significant material consumption, as these vertical members must travel the full height of the unit. Another arrangement for receiving a bending moment due to the weight of the reinforcing bond is disclosed and described in U.S. Patent Nos. 3.46 to 847. In the construction according to this patent, the bending moment from the upper and lower reinforcing joints is used to act against each other by means of vertically extending rigid members. The first member extends downwardly from the upper reinforcing bond and the second member extends upwardly from the lower reinforcing bond. The two members overlap and adhere to each other so that horizontal forces can be transferred between the members at the point where the bending moment of each reinforcement bond gives the correct reinforcement force to the second reinforcement moment. This arrangement is repeated through the steam generator height reinforcement bonds as the pairs work, and as a result, the number of vertical members required is limited to half the number required in the other arrangements shown.

In such an arrangement, the members for transmitting horizontal forces between the overlapping, vertically extending members include flat surfaces cooperating with each other and a bolted joint between the two vertically extending members. Although, ideally, a system using flat surfaces abutting against each other between the two beams will provide a sliding surface contact between the two, in reality there will most likely be a horizontal line contact occurring at either the upper end of the lower beam or the lower end of the upper beam. Such a situation results in a rather uncertain contact between the two beams, bearing in mind the fact that the two reinforcing bonds involved can move at different speeds or at different magnitudes due to differences in thermal expansion. As a result, there is a very high chance that the beams will slip out of contact with each other and become inefficient. It would appear that the possibility of slipping away from the contact of the beams can be eliminated by using several bolted joints between the beams. However, such an arrangement brings with it a number of other problems, the most prominent of which is the problem arising from the correct orientation of the holes in the beams for manufacture. Another disadvantage of such an arrangement is the high bending stress to which the bolts are exposed. In the event of an overload, the bolts would be the first breakable element, followed by the contact arrangement described above with its associated disadvantages.

The present invention overcomes the disadvantages of prior art devices for transmitting horizontal forces in reinforcement bond level retention systems of the type in which the bending moment of the upper and lower reinforcement bonds is used to act against each other via vertically extending rigid members. The upper and lower vertically extending members are constructed and arranged to engage each other in a telescopic manner. Such an arrangement provides a stable, simple adhesion between opposing members without any of the disadvantages of the previously known arrangement.

According to the invention, there is provided a structure for maintaining the level of reinforcement bonds of a steam generator, the steam generator having a vertically extending furnace structure and a first reinforcing bond arranged at a lower level, the first support supporting said first reinforcement bond in the furnace structure in a free bearing manner. The steam generators also include a second reinforcement bond at the upper level and a second support supporting said second reinforcement bond in a freely load-bearing manner from the furnace structure. What is special about the invention is that it comprises a first member rigidly attached to said first reinforcing bandage and extending upwardly, a second member rigidly attached to said second reinforcing bandage and extending downwardly by slidably and telescopically engaging said first member which telescopic engagement of said first and second members contributes to the transfer of horizontal force between said first and second members in an intermediate plane between said first and second reinforcing joints, the intermediate plane being at a vertical distance from said first and second supports which is inversely proportional to said first and second supports with respect to the bending moment about the respective support members.

To make the invention easier to understand, it will be explained in more detail below with reference to the accompanying drawings, in which Fig. 1 is a plan view through a steam generator furnace showing a general arrangement of reinforcing ties and reinforcing bond planar holders. Fig. 2 is a sectional view taken along line 3-3, Fig. 4 is a side view of another embodiment of a reinforcement bandage holder according to the present invention, and Fig. 5 is a sectional view taken along line 5-5 of Fig. 4.

Figure 1, which is a sectional view of the steam generator, shows a furnace 2, the walls of which are lined with a plurality of vertical steam-generating horns or tubes 3. These horns or tubes extend over the entire height of the steam generator and expand longitudinally as the unit approaches working. Because the parallel furnace wall tubes or horns are joined together laterally so that adjacent tubes or horns are welded together, the furnace also expands horizontally. In order to maintain the shape of the rectangular furnace under the pressure of the internal furnace, opposite reinforcing bonds 4 and 5 are placed on opposite walls, while opposite reinforcing bonds 6 and 7 are placed on an adjacent pair of opposite walls. These reinforcement bonds are arranged on several different levels and are thus supported 56585 as shown in Figures 2 and 4. The increased furnace pressure tends to press the tubes outwards against the reinforcing bond 4 and this reinforcing slide, which forms rigid, prevents the tubes from moving outwards. The reinforcement bond 5 performs the same function on the opposite wall. The fasteners 8 of the reinforcing ties are connected to each end of each reinforcing tie so that the force tending to move the reinforcing tie 4 to the right acts against the force tending to move to the left of the reinforcing tie 5. These reinforcement bandage fasteners 8 are made in several parts, whereby the part 9 remains in close cooperation with the furnace wall, so it approximates the temperature of the furnace tubes as far as they are covered, and the reinforcement bandage holder part 9 expands to the same extent as the furnace expands horizontally.

This causes the reinforcing ties to move outwards from each other as the furnace expands, thereby maintaining the same mutually spaced relationship with respect to the adjacent furnace wall tubes.

Figure 2 shows that the pipes 3 of the furnace wall support the lower reinforcement bond 4 by means of a bracket 17 and a bolt 18. A strong connection is provided between the brackets and the reinforcement bonds near the center line of the furnace, while at other points a cutting hole is provided so that the furnace can expand horizontally with respect to the reinforcement bond. The weight of the reinforcing bandage 4 provides a clockwise bending moment around the support bolt 18. If not counteracted by this, this bending moment would expose the pipes 3 to high bending stresses, and since these pipes contain water and high-pressure steam and are exposed to radiation from the furnace, such high stresses are unbearable.

Figure 2 also shows that the upper reinforcement band 22 is supported in the same way from the furnace tubes 3 by means of a second bracket 23 and a bolt 24. These reinforcing ties 22 likewise have a clockwise bending moment around their support member caused by its own weight. The rigid circular pipe part 25 is welded to the lower reinforcement connection 4 and extends vertically upwards therefrom. The second rigid circular tube portion 27 is welded to the upper reinforcing joint 22. The inner diameter of this second tube 27 is larger than the outer diameter of the tube 25 and extends vertically downwards and receives the upper end of the tube 25 in a telescopic manner.

56565

The result of the clockwise bending moment of the reinforcing bandage 4 is that the vertically extending member 25 tends to turn clockwise, i.e. to the right in the figure. Similarly, the clockwise bending moment of the reinforcing bandage 22 causes the vertically extending member 27 to tend to turn clockwise, i.e. in this case to the left. As a result of the beams 25, 27 tending to move in opposite directions, they come into contact with each other in the area of telescopic engagement and the opposite horizontal forces of the two beams tend to cancel each other, receiving the bending moments provided by the weight of the two reinforcing tie members 22, 24.

Because the two vertically extending tube members 25 and 27 are maintained at ambient temperature while the furnace wall tubes 3 are heated to about 370 ° C, it is possible that the two reinforcing bond members 22, 4 may expand vertically to varying degrees, with the upper and lower the sliding adhesion of the mutual telescopic adhesion between the vertically extending tubular member 25, 27 receives this difference in movement. In theory, the point of contact between the two members comes to level 28, at which point the resulting horizontal forces are sufficient to resist the bending moments of each reinforcement bond. When the weight of the reinforcing bonds is the same and their bending moments are the same, the distance between the center of the upper reinforcing bond 22 body and the intermediate plane 28 indicated by the reference mark L 1 is equal to the distance between the intermediate plane 28 and the center of the lower reinforcing bond 4 body , which distance is denoted by the reference notation I ^. When different bending moments occur in these two reinforcement bonds, the vertical distances Lj, and Ii2 are inversely proportional to the bending moment around the respective support of each reinforcement bond. If additional loads are applied to the reinforcement bonds, such as from the pipe support members, these loads are taken into account in determining L 1 and I 1 to calculate the correct intermediate level 28 so that horizontal forces can generate reaction forces against each other to counteract the bending moments of both reinforcement bonds.

Similarly, the reinforcing ties 5, 6 and 7 are connected to the respective reinforcing ties at the upper level and use a structure similar to that shown in Figures 2 and 3. The remaining reinforcing bonds at the different levels of the steam generator 8 56585 are treated in pairs in the same way as the reinforcing bonds 4 and 22. A horizontal force acting on the horizontal extending tube 25 produces a force on the lower reinforcing bond 4 towards the furnace wall. The same force acting on the tube 27 extending vertically in the other direction causes a force exerted away from the furnace wall on the upper reinforcement bond 22. To avoid that it is necessary for the furnace wall structure to absorb these horizontal loads, an arrangement identical to Figure 2 on the opposite side is used. the reinforcing bond 5 is arranged directly opposite the reinforcing bond 4 and the second reinforcing bond is arranged directly opposite the reinforcing bond 22. The horizontal force acting on the upper and lower reinforcing bonds is then transmitted by the connecting rods 8, 9 so that any need for removal of such horizontal forces .

Figures 4 and 5 show an alternative arrangement in which all the stress-specific features of the reinforcement bonding system are the same as those shown in Figures 2 and 3, except that the vertical tube 29 extending downwardly from the upper reinforcement bond 22 is made of a rectangular, channel-shaped member. This rectangular channel-shaped member 29 similarly engages telescopically and slidably in a tube 25 extending upwards from the lower reinforcement bond 4. The relationship between the moments and the corresponding forces is the same as in the first described embodiment.

Although certain embodiments have been shown and described above, it is to be understood that this is done in an illustrative rather than a limiting sense, and that changes and modifications may be made to the invention without departing from the spirit of the invention. The invention is therefore not limited to the exact details set forth herein, but covers such changes and modifications as fall within the scope of the appended claims.

Claims (2)

66585 1. Anordning för att bibeh &lla niv & n förband f & en Änggenerator aom har en vert-tikalt expanderande ugnskonstrutkion, vilken Anggenerator har ett första förband vid en nedre niv &, ett första uppbärande päts, för nänmda första första första första frör änggeneratorn även har ett andra förband vid en Övre niv & och ett andra stöd uppbärande nänmda andra förband fr & n ungekostruk-tionen p & ett fribärande sätt, kännetecknad av ett första organ (25) styvt fäst vid nämnda första andra organ (27) styvt fäst vid nämnda andra förband (22) och sträckande sig ned & t och glidbart och teleskopiskt ingripande med nänmda första organ, vilket teleskopiskt ingrepp för nänmda första och andrara organ (25, 27) medger överföring k och andra organ vid en mellanliggande nivä mellan nämnda första och andra and förbandsniv & er, varvid den mellanliggande niv & n ligger p & ett vertikat avst & nd fr & n nän mda första och andra stöd som st & r i omvänd proportion mot böjningsmomentet för n & mwdw. första och andra vertikaletag nmt deras respektive stöd. A device for maintaining the level of a reinforcing bond of a steam generator having a vertically expanding furnace structure, the steam generator having a first reinforcing bond at a lower level, a first support member for supporting said first reinforcing bond from said furnace support in a free-bearing manner, characterized in that it comprises a first member (25) rigidly attached to said first reinforcing bandage (4) and extending upwards, a second member (27) rigidly attached to said second reinforcing bandage (22) and extending downwardly by gripping slidably and telescopically to said first member, the telescopic engagement of said first and second members (25, 27) contributing to the transfer of horizontal force between said first and second members in an intermediate plane between said first and second reinforcing bonding planes, the intermediate plane being at a vertical distance from said first and second supports that is inversely proportional to the bending moment about said respective first and second uprights. Device according to claim 1, characterized in that said first member (25) comprises a first tube of circular cross-section welded to said first reinforcing joint (4) and extending vertically upwards, and in that said second member (27) comprises a second round member. a tube having an inner diameter larger than the outer diameter of said first tube and extending vertically downwardly telescopically and cooperating with said first tube. Device according to claim 1, characterized in that said first member (25) comprises a tube of circular cross-section welded to said first reinforcing joint (4) and extending vertically upwards, and in that said second member comprises a rectangular tube (29) having the inner surface-to-surface dimension is larger than the outer diameter of said tube and extends vertically downwardly telescopically into said tube. Device according to claim 1, characterized in that the bending torque of each reinforcing band around its respective respective support member is equal and that the transfer of the horizontal force takes place in a plane equidistant from said first and second planes of the reinforcing band. Device according to one of the preceding claims, characterized in that the connecting members (8, 9) of the reinforcing ties are arranged to fasten each end of the upper reinforcing bond on one side of the furnace to the corresponding end of the upper reinforcing bond on the other side of the furnace. each end of the reinforcing bandage on the other side of the oven to the respective ends of the reinforcing bandage on the opposite side of the oven. 2. Anordning enligt krav 1, kännetecknad av att nämnda första organ (25) innefattar ett första rör med circulär tvärsektion fastsvetsat vid nämnda första förband (U) och sträckande sig vertical upp & t, och att nra närnt organ (ett) with the inner diameter of the inner diameter