DD292637A5 - PROCESS FOR PREPARING PHOSPHOR (III) OXIDE - Google Patents

Abstract

The invention relates to the preparation of phosphorus (III) oxide from elemental phosphorus by reaction with oxygen / nitrogen mixtures. P4O6 can be used as starting material for the synthesis of a variety of organophosphorus compounds. The aim of the invention is to produce P4O6 in yields of 85% at Phosphordurchsaetzen of 10 kg / h and thus reduce the process engineering and energy costs for the separation of by-products. According to the invention, the hot reaction gas stream is cooled to temperatures of from 2 200 to 1 600 K and, after comparison of the radial temperature profile, is quenched with an equilibrium equilibrium temperature and composition with respect to the target product P4O6. {Phosphorus (III) oxide; Method; manufacture; Elemental phosphorus; Oxygen-nitrogen mixture; Yield; Equilibrium temperature; quenching; Temperature profile, organophosphorus}

Description

For this 1 page drawing

Field of application of the invention

The invention relates to a process for the continuous production of phosphorus (III) oxide from elemental phosphorus by reaction with oxygen / nitrogen mixtures. P ₄ Oe can be used because of its high reactivity as a starting material for the synthesis of a variety of organophosphorus compounds.

Characteristic of the known state of the art

According to DD-PS 216516 P ₄ O _{6 is obtained} at normal pressure in yields> 80%, when reacting gaseous phosphorus with oxygen-enriched air in a reaction stage and the reaction product gas stream in three subsequent cooling stages cools, the cooling in the 1st Kühlstufo indirectly on 1600 to 1700K, in the 2nd cooling stage directly by nitrogen quenching to 700K and in the 3rd cooling stage with liquid P ₄ Oa or reaction product mixture to about 300 K. According to DD-PS 222268 high reaction temperatures can be avoided by the use of air as the oxidant while saving the nitrogen used for direct cooling. The cooling of the reaction products is carried out indirectly by means of water and air to temperatures of about 700 Kund then in a known manner with liquid P ₄ O ₈ . By this method, yields of P ₄ O ₆ of 70 to 75% are achieved.

Furthermore, a process for the production of P ₄ Oe has been proposed in which the reaction and quenching are carried out in a multi-component nozzle by a separate but simultaneous addition of the gas streams phosphorus, oxydation gas and quench nitrogen. The subsequent cooling is carried out in two stages - primarily by indirect cooling of Rep.ktionsgases to temperatures of 450 to 700K and secondarily formed with liquid reaction product. By this method, P ₄ O _{8 is obtained} in yields> 80%. The said processes have the disadvantage that, in their industrial application, substantially lower yields of P ₄ O _{6 are} achieved and thus a significant proportion of the phosphorus used as starting material is obtained as unwanted by-products, vc-wiojend as phosphorus suboxide and Rhosphordll / V) oxides. These by-products greatly impair the free flowability of liquid P ₄ O ₆ and lead to a deterioration of the economy of the process.

Object of the invention

The aim of the invention is to develop an economically and technologically favorable process for the continuous production of P ₄ O ₆ , which at phosphorus throughputs of> 10kg / h yields of P ₄ O ₆ of> 85%, based on the phosphorus used, allows.

Presentation of the essence of the invention

The invention has for its object to make the process for the preparation of P ₄ O ₆ so that the quenching stage fed reaction product mixture has an approximately uniform composition over the entire flow cross-section.

According to the invention, the object is achieved in that the reaction product gas stream obtained by reacting phosphorus with oxygen / nitrogen mixtures in the molar ratio P ₄ : O ₂ : N ₂ = 1: 2.5 to 3.5:> 0 to 25 after cooling a temperature of 2200 to 1600 K, preferably 1800K, is passed through a arranged in front of the quenching segment to equalize the radial temperature profile. The segment is made with high temperature resistant material that has sufficient thermal shock resistance and chemical resistance to the reaction product gas, such as. B. silicon carbide, lined.

If high-temperature-resistant material with good thermal conductivity is used and the realization of a relatively large layer thickness of the surface is not possible, the heat transfer resistance can also be reduced by multilayer design of the high-temperature material or by gas layers in the segment wall.

The free flow cross section of the segment is S 80% of the smallest flow cross section of the reactor. The reduction of free flow! the reaction product gas stream

By the procedure according to the invention a reduction or a reduction of the radial temperature gradients occurring by the indirect cooling of the reaction product gas stream is achieved so that the reaction gas mixture having a temperature-dependent thermodynamic equilibrium composition can be fed to the quenching stage with an optimum equilibrium concentration with respect to the target product P ₄ O ₀ , The invention will be explained in more detail with reference to a drawing.

embodiment

A gas burner, which is mounted on top of a tubular reactor for the production of P ₄ O _e , 12 kg / h of gaseous phosphorus mixed with 3.6Nm ³ / h of nitrogen at a temperature of 620 K, and oxygen in stoichiometric relation to the phosphorus with a temperature of 600 K supplied.

The reaction product gas is indirectly intensively cooled with water in the upper part of the reactor 1. After 23.4kW have been removed from the reaction product gas with the cooling water, the gas is passed through a 0.2m long, with a SiC pipe 3, air-cooled, made of the material X10 CrAI 24 existing Segrnent. The SiC tube has only half the inner diameter compared to the preceding reactor tube. Between SiC pipe 3 and surrounding air-cooled wall 2, an annular gap 4 of about 5 mm gap width was realized in which reaction gas is in the operating state of the reactor, whereby a thermal insulation of the SiC pipe is achieved. The reaction product gas enters the SiC tube 3 at a temperature of about 1900K and leaves it at a temperature of about 1850K and substantially balanced radial temperature profile. The temperature difference between the reaction gas and Siliziumcarbarbidrohrinnenwandfläche 5 is about 200 K. From the SiC-lined segment are discharged with the cooling air 0.7 kW. After leaving the segment to equalize the radial temperature profile, the reaction product gas is quenched by admixing 24Nm ³ / h nitrogen at ambient temperature and intensive contact with water-cooled walls in a quenching stage 6. In a cooled Sträder scrubber, in which the reaction product gas enters at a temperature of 620K, the condensation of P ₄ O ₆ and the by-products is carried out. There are 20.7 kg / h P ₄ O ₆ / by-product suspension obtained with a P ₄ O _e -Masseanteil of 85.6%. With the nitrogen 0.6 kg / h of gaseous P ₄ Oe are discharged from the condensation stage, which are processed in a packed column to phosphorous acid. The yield of P ₄ O ₆ with respect to the phosphorus used is 86%.

Claims (3)

1. A process for preparing phosphorus (III) oxide by reacting phosphorus with oxygen / nitrogen mixtures in the molar ratio P ₄ IO ₂ IN ₂ = 1: 2.5 to 3.5:> 0 to 25, characterized in that the reaction product gas stream after cooling to temperatures of 2200 to 1600K, preferably 1800K, passed through an arranged in front of the quenching segment for equalization of the radial temperature profile of the reaction product gas stream and the quenching is carried out in a conventional manner. 2. The method according to claim 1, characterized in that the free flow cross-section of the segment: £ 80% of the smallest flow cross-section of the reactor. 3. The method according to claim 1 and 2, characterized in that the segment is lined with SiC moldings.