DE590903C - Lead chambers for the production of sulfuric acid - Google Patents

Description

Lead chambers for the production of sulfuric acid They are lead chambers Known for the production of sulfuric acid, in which the height is the width and length significantly exceeds. Such lead chambers have also been proposed to be connected by flat lines arranged in the lower part of the chambers (German Patent 346 2g6).

The present invention takes this further Chambers, which results in a significant increase in performance. First of all, it exists in that not only the chamber height, but also the chamber width is considerably larger is than the length of the chambers. To ensure proper flow in these chambers To bring about the gas, the invention brings a special design to the below arranged connecting lines and for their production inside the chambers certain internals.

This arrangement results in a particularly favorable ratio between the surface area of the chamber walls and the volume of the chambers. Tests have shown that for 1 m3 of chamber space, 10 kg of sulfuric acid, calculated as monohydrate, can be produced per day and only 0.8 to 0.2 g kg of nitric acid of 1.333 specific weight per 100 kg of monohydrate are consumed if that The ratio between the surface area of the chamber walls in m2 and the volume of the chamber walls in m3 is approximately i and does not exceed a value of 1.2. For example, in a chamber system with a surface area of 5000 m2 and a volume of 5000 m3 produce at least 50 to 60,000 kg monohydrate per day, resulting in combs of 15 to 25 m in height and an equal width, the length of the chamber being advantageously measured at about 2.5 to 5 m.

In a known manner, 5 to 10 such chambers become a system arranged one behind the other and connected to one another by short channels provided at the bottom. The reaction gases flow through the channels simultaneously, but in the opposite sense and the acid products. According to the invention, these channels are now in slot-shaped lines divided, which are arranged at a distance from each other.

In the accompanying figures are some exemplary embodiments of these Arrangement shown, at the same time the gas flows occurring by arrows are indicated, namely Fig. i and q. a vertical section through the system in the direction of the chamber length, Fig. 2 and 5 a vertical section in the direction of the chamber width, Fig. 3 and 6 a horizontal section through the chamber system and Figs. 7 to g details of the channels.

It should be noted that in Fig. 3 and 6 on the plane of the drawing vertical arrows. are indicated in the usual way by dots, if they step out of the plane and through crosses as they step into the plane.

In Fig. I to 3 the incoming one flows Gas flow through the slot-shaped lines enter the chambers and when its flow rate is big enough, about the middle of the chamber. Here the gas flows in the form of streams i upwards and falls as streams 2 and 3 on the outer walls of the chambers. These Flow is supported by the fact that the gases from the outside are natural or artificially cool down the cooled walls of the chambers. In this flow process an exchange of heat and nitrogen oxide takes place through turbulent movements.

In order to achieve that the falling gas stream 2 through unhindered the incoming gas flows i can enter the outlet side of the chamber is, as can be seen from the drawings, the connecting line between the individual Chambers divided into, for example, four sections that are spaced from each other are arranged. This allows the gas streams falling on the inflow side 2 at the points 7a not used by the entering gas streams be bypassed between the lines on the rising gas streams i and get to the other side, from where it merges with the descending stream 3 can enter the following chamber through the connecting line. Experiments have shown that the gas velocity described here Flow processes can be carried out without interference if the dimensions of the Chambers are not extremely large.

The idea of the invention also applies to very large and highly stressed chambers can be made useful, as shown in Fig.q and 6, at the points where the broad side of the chamber is not interrupted by the slot-shaped lines is to arrange hood-shaped channels that are open to the broad side of the chamber, like this is shown in Figs. 7 and 9 on a larger scale. These channels can be made of masonry 6, which is made of brick or other resistant material, exist and are advantageously closed at the top by plates 7. You leave between their openings and the broad sides of the chamber free spaces that are approximately the same thickness of the falling gas flow. The upper limit 7 is advantageous above the level that is laid through the upper edge of the slit-shaped lines, as shown in fig. q. and 9 can be seen.

The falling gas streams pass through these hood-shaped channels 2 passed unhindered between the rising gas streams i and combine on the outlet side of the chamber with the gas stream 3 falling there, to with to enter the next chamber together.

The mutual disturbance of the gas flows can be further reduced by that one over the upper edge of the slot-shaped edge 8 approximately a horizontal, in the wall protruding into the chamber is arranged, which is indicated in Fig. 7 to 9 by the number io is designated. This wall is slightly lower than the upper limit 7 of the hood-shaped Channels 6 and extends into the chamber for about a third of its length.

With this arrangement, the incoming gas flows i are safe to to the middle of the chamber and climb up there. The falling gas stream 2 is then deflected when it hits the wall io and by the hood-shaped Channels 6 passed through to the exit side of the chamber.

The present inventive concepts are suitable for each lead chamber Size. You can achieve a significant increase in performance, while the consumption increases nitrous acid is very low.

Claims (1)

PATENT CLAIMS: i. Lead chambers for the production of sulfuric acid, the height of which considerably exceeds the length and which are only connected to one another by lines located in the lower part, characterized in that the chamber width is considerably greater than the length and the connecting lines (8) are flat, approximately corresponding to the chamber width , divided into individual sections, at a distance from one another arranged slot-shaped lines, which protrude slightly above the acid level, are formed. z. Lead chamber according to claim i, characterized by hood-shaped channels (6) in each chamber open to the broad side of the chamber, which are arranged between those points where the broad side of the chamber is not interrupted by the slot-shaped lines and between their openings and the broad sides of the chamber, for example the thickness of the falling gas flow (a, 3) leave free spaces corresponding to the thickness, the upper end (7) of these channels (6) running above the plane laid through the upper edge of the slot-shaped lines. 3. Lead chambers according to claim i or 2, characterized by walls (io) projecting horizontally into the chamber over the upper edge of the slot-shaped lines (8).