BE392993A - - Google Patents

Description

       

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  Improved process and apparatus for the manufacture of nitrates.



   This invention relates to an improved process and apparatus for the manufacture of nitrates. More particularly relates to a process and apparatus for making an alkali metal nitrate by treating a solution containing an alkali metal nitrate. by gases containing nitrogen peroxide to convert the nitrite into the corresponding nitrate.



   We already have. proposed to absorb gases containing nitrogen oxide by alkaline liquors to produce a solution containing both a nitrate and a nitrate, then to oxidize the nitrite contained in solutions of this kind by treating these solutions with peroxide of nitrogen or nitric acid and absorb the residual gases from this treatment with basic solutions to produce a substantially par nitrite.

   Processes of this kind give rise to two products, namely a

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 nitrite and a nitrate,
We also already have. proposed to treat a solution oon-
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 holding both a nitrite and a nitrate per nitrogen peroxide-containing gas to oxidize the nitrite in eleven series of reaction vessels through the gas which passes through the gas containing nitrogen peroxide being conducted into the opposite sounds and SUOOla8iTcm.nt through the various rdao- tion reoipiente.

   An oxidation chamber that is interposed between each of the containers and the next container of the production so that the nitric oxide contained in the gases leaving one of the containers can be converted into nitrogen peroxide before the gases have entered the container. the following container
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 before;

   and the residual gases from the last vessel are absorbed by a basic liquid to produce a nitrite-nitrate solution for the treatment carried out in
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 The series of rdeipiente by fresh gases containing nitrogen peroxide. A process of this kind involves the construction of a large and complicated plant in which each reaction vessel is provided with an oxidation chamber in series with The reaction vessels and the oxidation chambers must be of sufficient size to allow the
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 passage of all 149 gases through the various receptacles and ohmbr4et, Loreq, u'il it is not a matter of reacting relatively large quantities of matter, an installation of this type 04 ooitteu.1 and .n, oJ1brant ..

   and he this Boa- vent impossible to employ for the construction of a
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 apparatus of adequate dimensions the materials required which are resistant to liquor and gas extremely oorrotia ,, a further,, in, 811ppoaa.t that a large installation of type o be constructed using the materials. of which we die- P0846 its exploitation involves the application of considerable pressure. "4.anQ the aim of repressing a large" 'z' * ". * '' ... -",, ... x, . , volume of gas at the desired speed to milking lea reoipienta

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 reaction units arranged in series,
The intention is to provide a process that can be implemented in a simple and relatively inexpensive device.
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 expensive and a device, in which it is not necessary.

   re to provide an oxidation chamber for each of the reaction vessels.



   A further subject of Bile is a process for the manufacture of nitrates which can be carried out in a composite apparatus.
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 are relatively small which can be constructed from materials extremely resistant to attack by corrosive gases and liquids: and a process capable of being carried out in a continuous and efficient manner to effect substantially complete recovery of the oxygenates from Nitrogen contained in a gas as a single nitrate product without the need for nitric acid
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 specially prepared.

   Other aims of the invention will become apparent during the description given below *
In the practice of this invention, we
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 Tertilates the nitrite that a solution contains. corresponding nitrate by successively treating the solution with a series of distinct portions of a gas containing
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 nitrogen peroxide, After the treatment of the nitrite solution, when the residual gases have been combined, and in particular after they have been subjected to oxygenation, these gases can be easily and substantially completely absorbed by an alkaline liquor to generate a solution containing a nitrite,

   By treating this nitrite solution in the aforementioned manner with further quantities of gas containing oxy-
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 hampered by nitrogen and absorbing the residual compounds by additional alkaline liquor in the manner previously described, a nitrate can be produced in a manner.
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 gon continues by a p1'Oo.d 'àane which an oontaot t

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 quate is ensured between the gases and the liquor without requiring excessive pressures to force the gases through the apparatus,

   and wherein a given amount of oxygenate nitrogen and alkaline material is regularly and continuously converted into a substantially equivalent amount of nitrate. The present process is generally applicable to the preparation of nitrates starting from alkaline liquors such as solutions of calcium hydrate or milk of lime or starting from liquors containing basic compounds of alkali metals such as carbonate hydrate.
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 sodium or 44 potassium
In order to better understand the nature and the objects of this invention, a more detailed description will be given hereinafter with reference to the accompanying drawing which re
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  Thus, one embodiment of the present method practiced in a suitable apparatus, the apparatus shown comprises a combined dream, refrigeration and oxidation chamber 1 into which hot gases containing hot gases are introduced through a pipe 2. nitrogen oxide or other oxygenates of nitrogen
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 which will all be understood hereinafter under the term "nitrogen oxide". these gases arriving, for example, from the heat exchanger apparatus forming part of an installation for the catalytic oxidation of ammonia, not repnsln- ted.



   The gas containing nitrogen oxide is cooled in chamber 1 by its direct contact with dilute nitric acid which, in the lower part of the chamber, is recirculated by means of a pump. 3 who the
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 returns through a refrigerant 4 to the sudr (0n-r4 part of this chamber, from which it comes into direct contact with the gases which the said chamber contains.

   As the temperature of the gases decreases, the vapor cl4ga which

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 may condense and some of the oxide
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 d <nitrogen can) be absorbed to generate further amounts of dilute nitric acid By cooling the
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 gas as described, the amount of deagote oxide removed is reduced to a minimum, so that the content
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 Nitrogen oxide from the gas exiting from chamber 1 is taken for nitrate production as will be described later.

   The quantity of dilute diacid which is added can be kept substantially constant.
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 circulating through the refrigerant and the oxy chamber (lation by withdrawing through a pipe 70 an amount of aid equivalent to that generated in the chamber. This dilute nitric acid can be employed in any way
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 desired. For example, we can neutralize it at. using sodium carbonate solution and reusing to prepare the liquor which is used to absorb the oxide
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 nitrogen as will be described later. He oon. The chamber 1 is made of acid resistant material, eg chrome iron.

   The lower part of the chamber preferably contains a layer of filling material 63 suitable for promoting intimate contact between dilute nitric acid and the gases * On the other hand, the upper part of the chamber is devoid of filling material and its capacity is large enough that after the gas containing nitrogen oxide has been cooled in the lower part of the chamber to a temperature suitable for the conversion of the lower oxygenates to a- peroxide.
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 zote, for example approximately 4 300 C * this gas reacts with the oxide it contains to convert these compounds
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 lower oxygenates, such as d-eatoteo dioxide to nitrogen peroxide (mixture of rz0 and az 0),

   so that the gas leaving chamber 1 contains a proposal of nitrogen peroxide which contains for the oxidation of sodium nitrite as will be described more

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 far, a suitable degree of oxidation of nitrogen oxide has been achieved when this oxide contains, for example,
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 Approximately 80 bzz or more of peroxide If the gases entering from pipe 2 do not contain a sufficient proportion of oxygen to react with nitrogen 1-toxide to generate nitrogen peroxide, it can be suppressed. additional ksoxygdbe, preferably in the form of air, in chamber 1,

     
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 gas link containing peroxide cl $ nitrogen4 pas8fnt from chamber 1 to manifold 5 in which they are
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 divided into a series of portions and introduced into the lower part of a series of oxidation tubes 6a, 6b, 6 * t 6d, 61 and 6f made of acid resistant material and, filled with an inert material such than the odds. The euf $ rieuze part of each of these towers is connected to a collector T which collects and brings together the
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 residual gases from the various towers and ambbe at the lower part of an absorption tower 8 ,, The top of the absorption cough 8 communicates with the subject of a second absorption tower 9 through a pipe 10.

   The gas exhaust pipe 11 allows the unabsorbed gases actually eideal from the absorption tower 9 to escape to the atmosphere or leads them to any desired location for use.



  The absorption tower t is supplied by a pipe read from an alkaline liquor, which is preferably a sodium carbonate solution containing about 220 grams of sodium carbonate per liter. Liquor
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 arriving through pipe 12 mixes in the lower part of tower t with a similar mass of liquor which has been brought into the tower into contact with the gas containing nitrogen oxide, and mixes and returns by pipe
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 23,

   pump 22 and pipe 24 at the top of the tower and descends through this tower on contact
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 se * containing nitrogen oxide A part of jazz

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 circulating liquor is transferred through an overflow pipe 13 of the. lower part of tower 9 to the lower part of tower 8 where. it mixes with a mass of liquor which has previously been withdrawn from tower 9 and treated in tower 8 with gas containing nitrogen oxide, the mixture being returned through a pipe 16, a pump 25,

   a pipe 27 and a condenser 68 at the top of the tower 8 to go down again through the tower in contact with the gas arriving through the pipe 7 The sodium carbonate solution absorbs in the absorption towers 8 and 9 the oxy - nitrogen gas passing through these towers to produce a sodium nitrite solution containing a certain proportion of sodium nitrate and a small amount of sodium carbonate.

   It has been found that by controlling the oxidation of the nitrogen oxide absorbed by the sodium carbonate, it has been found that 15 to 20% of the total amount of nitrogen contained in the liquor leaving the alkaline absorption towers are present in combination as the nitrate in this liquor, effect the efficient treatment of the liquor in the oxidation towers for the oxidation of its nitrite content, In some cases it may be desirable that the oxidation is carried out to a higher degree, and marls until the complete conversion of the lower oxygenates into nitrogen peroxide, before carrying out the absorption by the sodium carbonate solution,

   in which case the nitrogen content of the liquor leaving tower 8 would be composed of equal proportions of nitrogen as nitrate and nitrite. By increasing the degree of oxidation of the gases before absorption, the proportion of sodium nitrite in relation to the sodium nitrate contained in the liquor carried from the absorption towers to the oxidation tank is reduced and, in this way, the charge imposed on these last rounds.

   Towers 8 and 9 can be made of iron, to facilitate the absorption of nitrogen oxides. tower 9 is guarded

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 nie of an inert material 14 (preferably constituted by ceramic rings) above which the solution flows and is exposed to intimal contact with the gases * The upper part of tower 8 is also (preferably lined with 'a filler 14,

   but the lower and substantially the large part of this tower is left wrinkled in order to constitute a relatively large capacity in which the nitrogen oxide arriving through the pipe is oxidized by the oxygen contained in the gas or by 1 "oxygen admitted to tower 8 through a pipe 15. preferably in the form of air. The alkaline liquor passing through towers 8 and 9 is kept at a temperature suitable for absorption of nitrogen oxide, which temperature is preferably less than 40. 0 enviroh.



   From the lower part of tower 8, the solution containing sodium nitrite and sodium nitrate is conducted through a pipe 26 to the lower part of tower 6f where. it is mixed with the liquor which holds this part of the tower, the mixture being transferred by a pump 37. a pipe 17, a refrigerant 47 and a pipe 38 to the upper part of this tower from which it descends through the tower eh contact with the gases containing nitrogen peroxide which passes through said tower.



  From the lower part of this tower, a part of the solution which has flowed through said tower is passed through an overflow pipe 42 to the lower part * of tower 6e, from where the liquor is returned by a pump 35, a pipe 18, a refrigerant 46 and a pipe 36 at the upper part of this tower in order to descend through the tower in contact with the gas charged with nitrogen peroxide arriving through the pipe 5, Likewise way, part of the solution is transferred from the lower part of each of turns 6e, 6d, 6e and 6b to the next turn of the series by,

   overflow pipes

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 19, 3a, 21 and 28, respectively, and, in each of the towers, the solution is recirculated, so as to pass into contact with the gases passing through these towers, by pumps 39, 40, 41 and 43, of the ttyaux 29. 30, 31
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 and 32, refrigerants 33 34, 44 and 4S and pipes 48, 49 ,, 10 and il. respectively, During the passage of the solution through the series of turns 6f, 6e, 6d. 60, 6b and 6a, the sodium nitrite which it contains is oxidized by the absorbed nitrogen peroxide, and a solution composed substantially of sodium nitrate and nitric acid is withdrawn from the interior part of tower 6a by a pipe 52.

   To ensure the complete oxidation of sodium nitrite, the liquor which
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 contains tower 6a increases strength until sufficient excess nitric acid exists to ensure
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 .ozydation of the small amount of sodium nitrite still contained in the solution and, preferably, 12
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 µ ao grams of nitric acid per liter of solution, so that the liquor comes out of the tower.

   As the degree of absorption of nitrogen oxide by the sodium nitrite liquor rapidly decreases as the temperature rises. the liquor passing through the
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 oxidation towers is maintained at a reasonable temperature, preferably less than about 40 ° C. The temperature is extracted and controlled by corner-cooling the liquor, while it is recirculated through the liquor. turns, in refrigerants 47 # 46, 33, 3 44 and 45, in which the solution passes indirectly
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 in contact with a suitable coolant. As indicated in the drawing, the tO8 9, 8, 6, 6 and t'60.



  6b and 6a are placed successively at lower and lower levels so that the solution t1'aTs' .l: 1S "installation while passing from one tower to the next under the ae- tion of gravity and that the flow of each turn at the
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 series livening tower by overflow pipes

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 which connect the towers is determined by the amount of sodium carbonate solution arriving through pipe 12 into tower 9 per unit time.

   A long contact period is ensured between the gases which flow through the various oxidation towers and the solution within these towers by producing a repeated reactive contact of the solution with the gas stream arriving through the tower. pipe 5 and passing through each of the towers.



   Bn proceeding as described above with a nitrogen oxide gas obtained by the oxidation of ammonia, it is determined that about 10% of the nitrogen oxide is absorbed by the gas in the refrigeration chamber and d oxidation 1.

   The amount of nitrogen oxide absorbed in the absorption tower group is approximately 85-90% of the total amount of oxide contained in the gas resulting from the oxidation of ammonia. The amount of oxide absorbed in 149 oxidation towers to provide the nitric acid content of the sodium nitrate solution withdrawn from these towers is therefore relatively small.



   The sodium nitrate solution withdrawn from tower 6a through pipe 52 and which contains some absorbed nitrogen oxide, nitrous acid and nitric acid, is admitted to the upper part of a tower 53 in which it is treated with air admitted to the lower end of this tower through a pipe 54. The solution releases the absorbed nitrogen oxides, which is conducted out of the tower 53 through a pipe 55 and can be mixed with the gases from manifold 5. Most of the nitrous acid in the solution is also broken down by the treatment of the solution with air in tower 53.

   The sodium nitrate solution leaving the tower 53 is transferred through a pipe 56. using a pump 57, to

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 a reservoir 58 in which it is mixed with a sufficient quantity of sodium oarbonate solution admitted through a pipe 59 to neutralize the nitric acid which it contains and to produce a substantially pure sodium hitrate solution which withdrawn from reservoir 58 through pipe 69. The gases liberated by the reaction of nitric acid and sodium carbonate solution in reservoir 58 may be conducted to manifold 5 through pipes 60 and 55.

   The sodium nitrate solution which is withdrawn through pipe 69 may contain a small amount of sodium nitrite resulting from the neutralization of the nitrous acid which has not been copied into tower 53. One can see. center this nitrate solution and collect by crystallization the sodium nitrate it contains or subject the solution to any desired treatment to collect the sodium nitrate from the solution, it is preferable to evaporate this solution in an evaporator multiple-acting, shown at 61. so as to. precipitate solid sodium nitrate.

   This nitrate is conducted in the form of a slurry through a pipe 62 to a filter 64 in which the mother liquor is separated from the solid sodium nitrate and returned through a pipe 65 to the liquor which is subjected to concentration in the last stage of evaporator 61. The solid sodium nitrate withdrawn from filter 64 can be dried in a rotary drier or otherwise processed for processing into a commercial product.



   As stated previously, sodium nitrate solution contains some sodium nitrate in dissolved state. It also contains a small amount of sodium carbonate which has not been decomposed in the treatment of the sodium nitrate solution in the neutralization vessel 58. The concentration of these

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   impurities increase as the sodium nitrate solution concentrates in evaporator 61, and to prevent an excessive amount of impurities from being present and in solid sodium nitrate withdrawn from filter 64,

   it is preferable to keep the concentration of sodium nitrite and sodium oarbonate in the liquor transferred from the evaporator to the filter between defined limits, which depend on the permissible content of the sodium nitrate product of these impurities Adjustment of the impurity content of the product can be carried out by diverting part of the mother liquor returning through pipe 65 to the last effect of the evaporator 61 and by returning otite part, through pipe 66, to the pipe 26, where it mixes with the sodium nitrite solution going to the oxidation tower 6f ,, In this way,

   by deriving per unit time from the mother liquor in the pipe $$ a proportion of liquor such that the remaining or main portion contains the same weight of sodium nitrite and sodium carbonate as that introduced per unit of time into the evaporator by the solution supplied to said evaporator through pipe 69, the concentration of impurities in the liquor passing from the evaporator to the filter is kept constant and determines the amount of impurity contained in the sodium nitrate product withdrawn from the filter. This liquor returned to the process, which is a liquor saturated with sodium nitrate, is diluted with the solution withdrawn from pipe 69 by pipe 67 opening into pipe 66, so as to prevent the pre-oipitation of sodium nitrate by the cooling of the liquor in the pipe 66.



   It is evident that the impurity content of the sodium nitrate product can similarly be controlled by returning a sufficient amount of the mother liquor from the last effect of the evaporator to the oxidation towers.



  We see that, in both cases, the adjustment of the

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 The impurity content of the solid product is obtained by reaming ** part of the nitrate solution evaporated in the oxidation towers, where it is then treated with a gas containing nitrogen peroxide. ,of. Instead of introducing the returned liquor into the solution of sodium nitrite which is completely replaced, this liquor can be introduced into the solution passing through another element of the series of oxidation towers.

   The treatment. by nitrogen peroxide of the liquor brought back has the effect of converting by oxidation the sodium nitrite which this liquor contains into sodium nitrate and of decomposing the sodium carbonate of said liquor in order to convert it into sodium nitrate. This characteristic of returning from the mother liquor to the liquor being treated with nitrogen peroxide means that the impurity content of the sodium nitrate produced can be regulated in a simple and efficient manner, without loss. of material and without it being necessary to have recourse to an additional apparatus to purify the product ,.



   It will thus be seen that the present process, as described in the example above, consists essentially in the repeated treatment of a solution of a fried ni with separate portions of a gas containing. nitrogen peroxide to oxidize nitrite and convert it to nitrate. The residual gases are combined and absorbed by an alkaline solution, in such a way that a nitrite solution is obtained which, in a similar manner, is treated with nitrogen peroxide and thus converted into nitrate.

   The process can therefore be considered to include passing an alkaline solution continuously through a series of turns and countercurrently to gases containing nitrogen oxide in a continuous fashion. that said solution between socces- sively in contact with these gases to absorb the oxy-

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 of nitrogen and thereby producing a solution of a nitrite;

   and in then passing this solution successively and in series through a series of turns in which it comes into contact with a series of current gas dis- tinets (that is to say, not yet having been brought to the contact of nitrite solution) containing nitrogen oxide, to convert nitrite to nitrate by oxidation, the separate streams of gas moving in parallel to contact the nitrite solution.

   The alkaline solution is thus continuously and efficiently converted into a solution of the corresponding nitrate, by subjecting this solution to suitable treatments, the nitrate can be collected in a solid form,
It is evident that many modifications can be made to the particular process described above with reference to the accompanying drawing, For example, instead of the six towers provided for the oxidation of sodium nitrite liquor and two towers provided for the absorption of the residual nitrogen oxide by a solution of sodium carbonate, it is possible to provide a greater number or less of them in either group.



  In the embodiment described, the sodium cer- bonate solution and the gases containing nitrogen oxide are brought into contact by moving in the same direction in the tower 9, however, by passing the gases. gas from tower 8 in the lower part of tower 9 and removing the exhaust gases from the upper part of this tower, contact between the gas and the solution can, if desired, be achieved in said tower by making them move in contra = current. Instead, you apply a unique apparatus both for cooling it and for the oxidation of gases containing oxy-

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 of nitrogen, these two operations can be carried out in separate devices;

   it is well, if the gases available have a suitable composition and temperature, they can be passed directly into contact with the sodium nitrite solution,
Of course, the details of the method and of the constructions described above are susceptible to various modifications coming within the scope of this invention.



   CLAIMS
1. A process for producing a nitrate by treating a nitrite with a gas containing nitrogen peroxide, this process being characterized in that a nitrite is oxidized in the dissolved state by successively reacting the solution with portions separated from a gas containing nitrogen peroxide, substantially as specified.



   2. A process for producing a nitrate as specified under 1, characterized by the fact that the successive reactions are carried out in a series of stages in which the nitrite solution is brought into reactive contact with a different portion of fresh gas. oContaining nitrogen peroxide, substantially as specified.

** ATTENTION ** end of DESC field can contain start of CLMS **.


    

Claims (1)

3. A process for producing a nitrate as specified under 1 or 2. characterized in that the nitrite solution is repeatedly brought into retive contact with a stream of gas containing nitrogen peroxide, which is removed a portion of. the solution and repeatedly brought the removed portion into reactive contact with a second stream of gas containing nitrogen peroxide. in substance as specified, 44. A process for producing a nitrate according to a <Desc / Clms Page number 16> Any of the preceding claims, characterized in that oxygen compounds from nitrogen are absorbed by an alkaline solution to generate the nitrite solution to be oxidized, substantially as specified. 5, A process for producing a nitrate as specified under 1 and 4, characterized by the fact that the residual gases are combined before absorbing the oxygen-containing compounds of the nitrogen which they contain by an alkaline solution, in substance as specified. 6, A process for producing a nitrate as a specif. Referred to in 5, characterized in that the nitrite content of the resulting alkaline solution is oxidized in the same manner as for the original nitrite solution, substantially as A process for producing a nitrate according to any one of the preceding claims, characterized by applying a solution of nitrite of an aloaline metal, oxidizing the oxygenates of the nitrogen contained in it. the combined residual gases and these compounds are absorbed by a liquor containing a basic compound of an aloaline metal, in substance as specified. 8. A process for producing sodium nitrate according to claims 1 to 6, characterized in that the applied nitrite solution is sodium nitrite solution, substantially as specified. 9. A process for producing sodium nitrate as specified in 1, this process being characterized by subjecting to the treatment with nitrogen peroxide a solution obtained by absorbing oxygen compounds from nitrogen with sodium carbonate solution, the substance as specified <Desc / Clms Page number 17> 10. A process for producing sodium pirata as specified under 5 and 9. characterized in that the oxygenated nitrogen compounds which the combined residual gases contain are absorbed by sodium carbonate solution, substantially as specified, 11, A process for producing sodium nitrate as specified in 10, characterized in that a gas is used of which approximately 80% of the oxygenate content of nitrogen is in the form of peroxide. nitrogen and continued treatment of the sodium carbonate solution with this gas until the solution contains approximately 12 to 20 grams of nitric acid per liter of solution, substantially as specified 12. A process for producing a nitrate according to any one of the preceding claims, characterized in that the reaction of the gas with the nitrite solution is carried out at a temperature below about 40 C and that the gas is used. a gas in which approximately 80% of the oxygenate content of nitrogen is in the form of nitrogen peroxide, substantially as specified 13. A process for producing sodium nitrate according to any one of claims 9 to 9 is characterized in that the applied sodium carbonate solution contains approximately 220 grams of sodium carbonate per liter, substantially as specified 14. A process for producing a solid nitrate according to any one of the preceding claims, from the gemstone in which the nitrate solution o containing impurities and resulting from the treatment of the nitrite solution with nitrogen peroxide, collected therein is evaporated. the solid nitrate from the solution evaporated. and reduce the mother liquor to another portion of ni solution. trate in order to evaporate it. this process being characterized <Desc / Clms Page number 18> in that the impurity content of the solid nitrate is controlled by separating a portion of the evaporated nitrate solution and mixing it with the nitrite solution which is then treated with the gas containing nitrogen peroxide. nitrogen, in substance as specified. 15. A process for producing solid sodium nitrate as specified in 14 and of the kind in which the manner taken as a starting point is sodium nitrite solution and the impurities are sodium carbonate and sodium nitrite obtained by neutralizing the solution treated with nitrogen peroxide with sodium carbonate. characterized in that a portion of the collected evaporated sodium nitrate solution is mixed with sodium nitrite solution, substantially as specified. 16. A process for oxidizing the nitrite contained in a solution, this process being characterized by bringing into contact with this solution a gas containing oxygenated nitrogen compounds, the degree of oxidation of which corresponds to a higher content. to about 80% nitrogen peroxide and passing this gas and solution in intimate contact with each other, substance as specified. 17. An apparatus for producing a nitrate by practicing the process according to any one of the preceding claims. this apparatus being characterized by the fact that it comprises a series of towers, a device for passing a liquor to. through the various towers in series, a device for dividing a gas into a series of portions and for passing each portion through one of the towers and a device for gathering the residual gases from the towers, in substance as a special - cified. 18. A device as specified under 17, charac- <Desc / Clms Page number 19> This is by the fact that a device is provided for re-airing through each tower a portion of the liquor which has passed through that tower, in combination with a device for cooling the liquor thus recirculated, substantially as specified. 19. An apparatus according to claims 17 and 18, characterized in that the towers comprise an absorption tower and several oxidation towers and that a device is provided for passing the residual gases through the absorption tower. pooled from oxidation towers, substantially as specified. 20. A process for producing a nitrate by treating a nitrite with a gas containing nitrogen peroxide, the substance as specified. 21. An apparatus for producing a nitrate, a substance as specified and as shown in the accompanying drawing.