DE2141106B2 - Support element for catalyst meshes - Google Patents

Description

The invention relates to permeable multilayer materials for chemical or physical treatments at temperatures that vary within wide ranges, being below permeable multilayer Materials in the context of the invention are to be understood as combinations consisting of a Pad in the form of a net or the like. With a flat material made of a placed thereon Material that is chemically or physically active in the intended process

Precious metal gauzes are primarily characteristic examples of such multilayer materials to mention the chemical specific for catalysis Reactions in particular in the gas phase are used and on a support element of the one described here Type that gives the combination mechanical strength that the network alone cannot was exhibited. It is these combinations that are almost exclusively described below will. However, the invention is not limited to multilayer Materials of the above-mentioned type are restricted and, for example, also to multilayered ones Combinations can be used that consist of a support element and, for example, a flat filter material or a flat material, which in any other way a phasikahschen or chemical treatment of media is used, which optionally solids in more or less fine Suspensions included.

The structure of catalytic composite materials of the type in question here, in particular such Composite materials necessary for catalytic oxidation are determined by ammonia, possibly under pressure, poses problems due to the large temperature differences to which they are subjected and the excessive stresses are difficult to solve.

The noble metal networks used as a catalyst are very fine and have a very low mechanical strength Strength They must therefore be kept as flat as possible and be trimmed at a very large number of points. So far this has been achieved by a proportionate rough supporting structure and a distribution network attached to this supporting structure were placed on top of each other and attached to the distribution network, the catalyst network made of precious metal became. However, the supporting structure and the distribution network must be made of expensive refractory Precious metal alloys exist. It was suggested for the main supporting structure or as intermediate pieces non-metallic, less expensive refractories Materials to use, but these materials have poor thermal shock resistance.

The parts that form the main supporting structure Refractory alloys also inevitably have large dimensions and experience from For this reason, due to the temperature differences, strong permanent deformations that often occur quickly occur, so that the supporting structure is often replaced must become

Since the catalyst gauzes are generally horizontal and lying flat in cylindrical reactors, was the simplest method for

ίο creating a requirement for these networks then that a network of refractory wires was stretched in a ring or frame. The dimensional fluctuations However, the various parts of the supporting structure must be balanced when the catalyst meshes are not subjected to strong stresses that endanger their mechanical strength It would therefore be necessary for the support net to absorb these fluctuations and still maintain them the various phases of standstill, ignition or the start of normal operation and the Shutdown of the system remains in the elastic range.

If in the above special case the

catalytic oxidation of ammonia a round frame is used, which consists of a metal alloy with a thermal expansion coefficient of about 18 · 10 ^β and in which a wire mesh is directly attached, and if this wire mesh is in the elastic range during the various operating phases, namely

1) Ignition or start-up (frame at 150 ⁰ C, mains at 900 C),

2) Normal operation (frame at 400 ⁰ C, network at 900 ⁰ C,

3) Deleting or stopping (frame at 35O ⁰ C, mains at 50 ° C) and

4) downtime (frame at 20 ° C, network at 2O ⁰ C), the alloy of the wires must have a certain elastic limit and a certain coefficient of thermal expansion so that the network remains constantly tensioned, regardless of the sometimes different temperature between Frame and net during operation, one must compensate for the expansion differences that can occur in the operational phase in which the net is warmer than its frame with a pretensioning. At the moment of ignition, when the network has a temperature about 750 ° higher than the frame, the expansion difference corresponds

750 times 10 x 10 ^β = 0.0135 = 1.35%.

So that the network is the greatest at this moment Elongation due to its own weight and the stress on the catalyst does not sag, but rather remains even, a tension of zero is not enough just at this moment. That's why the theoretical preload increased to 50%, which corresponds approximately to a basic preload value of 2%.

The following voltages arise during the various operating phases

Downtime
ignition

Normal business. Business as usual .
Extinguish

Base value 2%
2% ~ (900-150)
• 18-10 ^e = 0.65%
2% - (900-400)
• 18-10 "= 1.1%
2% + (350-50)
■ 18 · 10- "= 2.54%

This means that a preload of 2% is essential so that the network can absorb the deformations, which are due to the elongation under the influence of heat. This is the first time through a with a A preload of about 2% preloaded support element that shows good creep behavior and is not stretched more than 1% in 10,000 operating hours.

1) If one considers the system after ignition (frame at 150 ⁰ C, load power at 900 ⁰ C), the diametrical wires have experienced the following expansion.

a maximum of 100 kg / mm ² results for a Young's modulus of 20,000 kg / mm ² at 50 ^° C

100 λ
20,000

A 61

All I

= «· (900 - 20)

The diametrical expansion of the frame results from the following equation:

Δ21
-

= 18 ■ 10- «· (150 - 20)

2) During normal operation (frame at 400 ⁰ C, network at 900 ⁰ C) the expansion of the diametrical wires is the same, but the frame has an additional diametrical expansion of

AiI
/

= 18 · 10- «(400 - 150)

Experienced.

When the diametrical wires in the aforementioned phase (1) at the lower end of the elastic Area are tense, and if you wish they in phase (2) the upper end of the elastic range, the elastic range

35

Ai I I

= 18 · 10- · 250 = 0.45 \

include.

Accordingly, with a Young's modulus of 15,000 at 900 ^° C., the alloy must have an elastic limit of

0.0045 x 15,000 = 67.5 kg / mm ²

45

at 900 ^° C. So far there is no alloy that ^{withstands such a tension at 900 °} C. and remains in the elastic range.
3) However, if there were such an alloy, it would still be required that the diametrical wires of the erase phase resist (frame at 350 ⁰ C, power at 50 ° C) at which a contraction of the diametral wires from

AJl
T

= <x (900 - 50)

55

and an extension of the frame of

ASl

—F- = 18 · 10- «· (350 - 150)

entry. In relation to phase (1), this corresponds to an expansion of the diametrical wires of

A 6 / A 41 A 51

= α · 85Ο + 18 · 10- «· 200

If one takes for the elastic limit of a technical high-melting alloy at 50 ⁰ C so that λ ^ 1.65 · 10 ~ ^β .

There is currently no technical high-melting alloy that has such a coefficient of thermal expansion having. The alloy must also be used for the construction to have a normal life have good creep resistance or stability, d. that is, it may, for example, in 10,000 hours do not have an elongation of more than 1%.

It is absolutely impossible to combine the above conditions in a single alloy. Mathematically, an alloy with a Young's modulus of 5000 would allow all you want To meet conditions if the creep resistance or stability would be sufficient, but such Module itself assumes a strong drop in stability in the elastic range. According to the invention this object is achieved by a support element for catalyst gauzes, which is characterized by is that it is formed from a wire spirals made from a refractory metal alloy "Articulated" mat is made up of wire spirals by interlocking each spiral with the neighboring ones Spirals are interconnected and that it is under a bias of about 2% in all directions is clamped in a frame of any shape.

In the above-mentioned case, the frame can be used as a support element of a catalyst network be round or, for example, rectangular when used as a support element of a filter cloth, or each have a different shape which adapts to the apparatus in which the particular multi-part construction is used will. The frame preferably consists of several independent segments with which the "articulated" Mat is connected. The segments themselves are with the help of clamping elements with a continuous External frame connected.

The spirals or coils that make up the "articulated" mat have a low Young's Pseudo modulus, although the Young's modulus of the wires forming the mat has a high value. It is in this way possible to meet the desired conditions at a much lower cost than so far to realize a support structure that, while it remains in the elastic range, in all Directions can be stretched very strongly, and when used for the oxidation of ammonia absorbs the deformations that affect the thermal expansion of the overall structure and parts of the Catalyst can accommodate including their own expansions. The mat is constantly without substantial slack during both the ignition, normal operation, and extinguishing phases the standstill tense.

Furthermore, the points of contact of the catalyst networks on such a support element are extremely numerous and sufficiently punctiform, so that the turbulence of the gas flows is considerably less and the usable surface of the catalyst is larger. These are two very big advantages that favor the efficiency of the chemical conversion of NH ₃ to NO.

5 6

The same advantages are similarly screwed in with the segments and through corresponding holes 6 Use of this support structure for the others are guided in the outer frame 4. The free end of this purposes mentioned above, e.g. B. as a support for filter bolts is provided with a thread at 7, the one elements and generally when using the nut 8 takes up, with the help of the mat 2 the Construction according to the invention for treatments 5 is given the desired prestress. A catalyst achieves at which the temperatures of the ambient network 9 made of noble metal, the edges of which by fixed temperature not only to high values as in the above clamp with arched plates 10, which with the written case rise, but also on very never- segments are screwed onto the segments 3 other values are falling. is held, rests on the support net 2 and touches

The highest elevations of each turn of the das are shown as examples in the figures

Embodiments of the support element in a con-support network forming spirals and thus has extremely

Structure shown according to the invention. numerous and closely spaced support

F i g. 1 shows a schematic plan view of a part of the points,

an "articulated" support network; Of course, any other method of attachment is possible

F i g. 2, an analogous view of a variant 15 of the support network 2 on the segments 3 is possible, e.g. B.

such a support network; by clamping as with the catalyst mesh 9 and

F i g. 3 shows a partial view in vertical section hanging on hooks or wedges,

a construction according to the invention in the case of applications The materials of which the construction is made

for the catalytic oxidation of ammonia. are dependent on the operating temperature

The in Fig. 1 and 2 shown support element in 20 and the chemical conditions in the interior of the

the construction according to the invention consists of a catalytic furnace or other treatment apparatus

an "articulated" mat chosen as wire spirals 1, la ratur. For example, it is used for oxidation

consists, with each spiral with the neighboring ones from ammonia to nitrogen dioxide a high-melting

Spirals is connected by "twisting into each other". ende alloy with the trade name »Fluginox

Mats of this type are from their use for the 25 N 45 "for the production of wires with 0.75 mm

Manufacture of metal mattresses known. Diameter used. This alloy has a

Each spiral can be made from a single wire with very high creep resistance or stability. These stand, e.g. B. from the in F i g. 1 shown wire 1, wires are paired to form spirals with a through or it can consist of several wires, e.g. B. two knives of 10 mm and a pitch of 15 mm Wires are formed, as shown at la in Fig. 2 30 shaped. The double spirals are used to form the posed. In the second case, the entire support network is twisted or screwed into one another. Of the cross-section of the wire has a higher elasticity aims. Behavior of the support network and can be any

In the case of the in FIG. 3 embodiment shown have height. Such a support network resists in

the multilayer construction is an articulated 35 cold state of well over 2% lying

Mat, which is round, for example, tension at its edges. Its coefficient of thermal expansion is

welded to segments of the frame 3, which carries force 18 · 10 ~ ^e , and its Young module is close to 10

coherently with a continuous outer frame 4 and thus far below the value of 5000 that the upper one

connected by means of bolts 5, which form in the limit according to the calculation set out above

Segments 3 parallel to the bisector of 40 is required.

1 sheet of drawings

Claims (1)

Claim Support element for catalyst meshes, thereby characterized in that it consists of a wire spirals (1,1a) from a high-melting point Metal alloy formed "articulated" mat (2), the wire spirals by interlocking jeaer spiral with the neighboring spirals are interconnected and that it is pretensioned by about 2% in all directions a frame of any shape is clamped.