DE648294C - Process for the catalytic oxidation of ammonia - Google Patents

Description

Process for the catalytic oxidation of ammonia during combustion From ammonia by means of air, the nitrogen present in the air regulates the combustion temperatures. If you use more or less high percentage oxygen instead of air, then you have to Combustion temperature can be regulated by other means. One has to do this water vapor is added to the combustion gas mixture, which acts as a cooling medium of atmospheric nitrogen takes over. Other gases, e.g. B. SO2 are already proposed been. These substances have to be removed from the gas mixture after combustion before the nitrous gases are oitydated to nitric acid and condensed. There is therefore a great deal of interest in reducing the amount of this coolant as much as possible to keep it small, as this creates additional costs. It is therefore also an attempt has been made to cool the combustion contacts directly with water, by letting the contact burn under a layer of liquid. In-the-transmission From these experiments on a larger scale one had to experience that a cooling of the Contact does not occur at all because the hot gas mixture flowing through the contact together with the radiating heat, @ prevents the coolant from contacting the Network comes into contact. It only occurs from the edge of the contact, where it is in the Contact tube is attached beforehand, a low cooling effect, while above the free cross-section not the contact, but only the already oxidized gas is cooled will. The result is rapid destruction of the contact and poor performance the apparatus.

It has now been found that the combustion of contact can be in a simple manner by overall cool t that is sprayed into the gas stream prior to combustion water in mist form. The finely distributed water mist particles evaporate immediately in front of and. in contact and remove the excess heat from the same. While the known method only uses heat extraction as a function of the specific heat of the cooling media, the present method mainly uses the evaporation heat of the water for heat extraction, which is known to be a multiple of the specific heat. For this reason, a much smaller amount of cooling is required for the above method compared to the known method, which is. has a beneficial effect both in the .Contact utilization and in the subsequent condensation of the water.

It was impossible to foresee whether a contact would also burn calmly and the same nitrogen oxide yields will result if liquid water is added to the gas mixture is added, since even with the finest atomization of the water the evaporating Water particles cause the gas mixture to increase in volume and thus causing a deterioration in the composition of the mixture. Have the trials but shown that the NO yields are not only the same, but sometimes even higher lie than with combustion with air.

Another unforeseeable advantage of the new process is that the sprayed water mist also eliminates the risk of explosion, so that the extensive safety measures, which when using pure oxygen otherwise necessary will come to an end.

In preliminary tests it was found in an apparatus made of glass that effective cooling of the platinum contact through direct spraying with finely divided water can be achieved without the nitrogen oxide yield being impaired. This observation is fundamental to the whole process, since the conception up to then it was prevalent that liquids of all kinds not only harm platinum contact, but also the yield also drops very sharply as a result. The tests have also confirmed this. If the water is not properly distributed or if the droplets are too large, an every point of conspicuousness in the contact is a dark point at which the oxidation is hindered so that decomposed ammonia gas can migrate through the contact. the The yield of nitrogen oxides drops very sharply. Only by using suitable Atomizer nozzles, which are quite. achieve a uniform cone of water dust, stab oxide yields could be obtained which were only slightly below 10000 total conversion lay.

The experiments were made of my equipment from your well-known corrosion-resistant. Chrome-nickel steel carried out with a contact network, which had 28 cm = surface. The spray nozzle was arranged below, and withdrawn so far that the Scatter cone just hit the entire diameter of the net evenly so that none or very little liquid hit the wall. With the right setting or when the network is heavily loaded, it could be achieved that no There was no return; the return is in no way disadvantageous, since it can always be used as a spray liquid, even if it contains ammonia can.

A mixture of 750 liters of ammonia gas and 1690 1960: o oxygen was passed over a network of platinum per hour. For the cooling of the contact with spray water, 8709 water per hour were consumed, which corresponds to a water consumption of about 2 kg / kg nitrogen passed through. The nitrogen yield was 95.20; 'o. Thorough cooling behind the contact initially gives a weakly acidic condensate which only contained 3.6% acid; In the next cooler an acid of. 1-2 percent by weight was already obtained, and the third one, in which the remaining water was removed, showed an acid of 60 percent by weight. The total amount that had been condensed as aqueous acid in the three condensers together was only 9.6 percent by weight of the total nitrogen used. The remaining nitrogen was obtained in the form of NO or NO., And could be partially liquefied as N.04 simply by freezing without pressure. This is only possible by using water sparingly with intensive cooling. In the gas itself after the condensation there were still around 630, 'o NO., Present. The nitrogen oxide concentration after contact with 48 percent by volume of NO in the gas was also as high as cannot be achieved by any other method. With the process one is thus able to obtain the largest part, namely around 900'o of the total NO, in the form of liquid nitrogen tetroxide, if a slight increase in pressure is combined with the freezing of the gases. For this, however, it is important that only a small amount of gas ballast has to be compressed. Of course, all of the nitrogen can also be obtained in the form of aqueous 60 to 70% acid.

A particular advantage of the present method is that any temperature that is still possible for the combustion is in contact with the same under constant load. can be adjusted. As is well known, in the usual ammonia combustion process, the temperature in contact, which in addition to the flow rate and the gas composition is decisive for the nitrogen yield, can only be regulated by changing the load or preheating. Independent temperature setting is not possible. Even with the known method of cooling by means of a layer of water under the contact, there is only a very limited possibility of changing the temperature, since the distance of the water layer from the contact, if it is to have any effect at all, can only be adjusted within very narrow limits. The present method makes it possible to maintain any practically occurring combustion temperature with constant gas composition, contact load, gas temperature, to be precise only by regulating the amount of cooling water sprayed to the contact. The following table shows the relationship between the contact temperature and the amount of cooling water used. A Cas mixture of 3 6o 1 Ammno> -niak and 975; 1: about 95% oxygen / hour was used. The amount of water is converted to i g per gram of permeated nitrogen. Amount of water temperature nitrogen oxide yield g / g N 2.4 800 '91.4% 2.0 850 ° 93, =% 1.47 900 ° - 96.80 / 0 0.95 950 ° 96.2% 0.42 ooo ° 9340/0. In. In the same way as the contact temperature, the contact load can also be changed within such extensive limits as was previously not possible. This is also very important for the acid operation, because it is no longer necessary to shut down some contact furnaces in the event of a temporary fluctuation in the acid consumption, but you can continue to operate the furnaces with a reduced load. Demand peaks can also be dealt with without further ado without switching on new ovens, simply by setting the spray water mix. The ones used with the present mesh size of 28 cm2. hourly quantities of ammonia could be between 125 and 165o 1 / hour. that corresponds to a net load change of 2.5 g to 33.0 g N / cm2 of contact net area. This extraordinarily strong change in elasticity by more than thirteen times is not possible with any of the known methods, e.g. B. with the known sub-layering of the network with water, the amount of gas passing through the water can only be changed within small limits, otherwise splashing and foaming occurs, whereby a direct contact of coarser parts of the water with the network takes place. However, this immediately results in the contact being extinguished at the point, which greatly depresses the yield.

In order to maintain a wood yield, in the present process in the case of large network loads, either twill or tissue is used as contact, or @ there are several layers of normal net arranged on top of each other. The. The yield can of course also be increased by using platinum rhodium , but it could also be done with Rei: »- platinum alone, for example, at 92o ° and a network load of 2ogN / cm2 area with a contact of three superimposed Achieve nitric oxide extraction of 97.3 percent by weight.

Claims (2)

PATENT CLAIMS: i. Process for the catalytic oxidation of ammonia, especially with high percentage oxygen with the introduction of water into the Reaction mixture before .dem contact, characterized in that the water through Nozzles immediately before .dem contact is introduced in the finest division in such a way that it is at least partially vaporized in the contact itself. 2. Procedure according to Claim i, characterized in that instead of water, ammonia-containing water is fed to the gas mixture in extremely fine distribution.