Classifications

• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01D—COMPOUNDS OF ALKALI METALS, i.e. LITHIUM, SODIUM, POTASSIUM, RUBIDIUM, CAESIUM, OR FRANCIUM
  • C01D13/00—Compounds of sodium or potassium not provided for elsewhere
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01B—NON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
  • C01B21/00—Nitrogen; Compounds thereof
  • C01B21/20—Nitrogen oxides; Oxyacids of nitrogen; Salts thereof
  • C01B21/50—Nitrous acid; Salts thereof
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2004/00—Particle morphology
  • C01P2004/60—Particles characterised by their size
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2006/00—Physical properties of inorganic compounds
  • C01P2006/80—Compositional purity
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2006/00—Physical properties of inorganic compounds
  • C01P2006/80—Compositional purity
  • C01P2006/82—Compositional purity water content
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
  • Y02P20/00—Technologies relating to chemical industry
  • Y02P20/10—Process efficiency
  • Y02P20/129—Energy recovery, e.g. by cogeneration, H2recovery or pressure recovery turbines

Definitions

• Sodium nitrite (NaNO 2 ), an inorganic compound, is formed by reacting nitrogen oxides (NOx) with sodium carbonate or sodium hydroxide solution.
• Sodium nitrite (hereafter referred as SNI) is obtained as yellowish white crystalline solid.
• SNI is used in wide range of industrial applications including, but are not limited to, dyes and pigments, metal/water-heat treatment, specialty chemicals, rubber industry, food, fertilizers, in manufacture of glass surface, and pharmaceutical compositions.
• any impurity or additional ingredient in sodium nitrite must be detected, quantified, and minimized in order to develop an improved form of sodium nitrite with minimal impurities should be prepared.
• handling crystals of sodium nitrite may be a tedious job due to lump formation and hygroscopic nature of the salt.
• the form of sodium nitrite may comprise a purity level between 99% to 99.2%.
• the form of sodium nitrite may also comprise an amount of sodium nitrate no greater than 0.7%.
• a water content may be no greater than about 0.5% by weight, wherein a heavy metal content is no greater than about 15 ppm.
• the form of sodium nitrite may contain no greater than about than about 0.05% by weight of chloride content, wherein an iron content is no greater than about 0.002%, wherein a content of lead is no greater than 0.0001 ppm, wherein a content of Arsenic is no greater than 0.9 ppm, wherein a content of potassium is no greater than about 500 ppm, and wherein a content of mercury is no greater than 0.0001 ppm.
• the form of sodium nitrite may be free of heavy metals such as Mercury (Hg), Arsenic(As) and lead (Pb).
• the form of sodium nitrite may comprise an amount of chloride ion impurity no more than 0.0092%. In yet another embodiment, the form of sodium nitrite may comprise an amount of ferric ion impurity no more than 0.001%. In yet another embodiment, the form of sodium nitrite may comprise an amount of sulphate ion impurity no more than 0.032% and an amount of Fluoride impurity is no more than 1 ppm. In yet another embodiment, the form of sodium nitrite may comprise an amount of sodium carbonate impurity is no greater than 0.1%. In yet another embodiment, the form of sodium nitrite may comprise an amount of an anti-caking agent no greater than 0.1%.
• a shape of a sodium nitrite granule is optimized as purified crystalline granule and the height of a granule form is between 5 to 6 mm and a width of the granule form is between 7 to 8 mm.
• the form of sodium nitrite may comprise a content of Copper is no greater than 0.15 ppm, a content of Zinc is no greater than 0.2, a content of cadmium is no greater than 0.1 ppm, a content of chromium is no greater than 0.1 ppm, a content of chromium is no greater than 0.1 ppm, a content of Manganese is no greater than 0.11 ppm, and a content of Nickel is no greater than 0.1 ppm.
• a process of obtaining an improved form of purified crystalline of sodium nitrite with minimum impurities is disclosed.
• the process may comprise a step of mixing a predetermined ratio of air and ammonia in a venturi body mixer; transmitting the air-ammonia mixture through a HEPA filter for filtering out impurities and to obtain a purified air-ammonia mixture.
• the process may comprise a step of transmitting the mixture of air-ammonia into the adiabatic burner to pass through a plurality of catalytic gauzes positioned as three pairs of two gauzes each at a predetermined temperature to carry out the selective oxidation process and to selectively obtain oxides of nitrogen.
• the process may comprise a step of saturating oxides of nitrogen using a waste heat recovery boiler (WHRB) to obtain a saturated NO 2 gas.
• WHRB waste heat recovery boiler
• the process may comprise a step of passing a saturated NO 2 gas through one or more absorption towers for absorbing the saturated NO2 gas in one or more absorption towers containing an alkali medium for selective formation of sodium nitrite slurry.
• the process may comprise a step of optimizing a concentration of sodium nitrite slurry using a crystallizer to obtain a crude crystalline form of SNI.
• the process may comprise a step of re-crystallizing the crude crystalline form of SNI by multiple washing of the one or more solvents and more preferably water for removing the maximum impurities.
• the process may comprise a step of obtaining the improved form of purified crystalline SNI with a purity level between 99% to 99.2%.
• the process may comprise a step of adding anti-caking agent to the crude crystalline form of SNI.
• a modified sodium nitrite (SNI) may be obtained in one or more improved form of purified crystalline SNI such as uncoated form of SNI, and coated form of SNI, are disclosed herein.
• SNI modified sodium nitrite
• Reference throughout the specification to “various embodiments,” “some embodiments,” “one embodiment,” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, appearances of the phrases “in various embodiments,” “in some embodiments,” “in one embodiment,” or “in an embodiment” in places throughout the specification are not necessarily all referring to the same embodiment.
• the improved form of purified crystalline SNI is enabled for complying with the standards and obtained by using filters, i.e. specifically modified particulate air (PA) filters.
• the purified sodium nitrite crystals may be further modified in to one or more forms differing in shapes, purity level and complying with the standards required in the application fields.
• a crude form of SNI may be obtained by changing the ratio of oxides of nitrogen (NOx) gases and introducing the saturated NO2 gas to the absorption tower comprising base slurries such as sodium carbonate or sodium hydroxide.
• an improved form of purified crystalline sodium nitrite (SNI) is obtained.
• the form of sodium nitrite may comprise a purity level between 99% to 99.2%.
• the form of sodium nitrite may comprise an amount of sodium nitrate impurity no greater than 0.7%.
• a saturated NO2 gas absorption from NOx gases enables reducing the amount of sodium nitrate content to less than 0.7%.
• a utilization of purified air-ammonia mixture for oxidation and to obtain oxides of nitrogen minimizes formation of impurities other than sodium nitrate at very primary stage of production of the improved crystalline form of SNI.
• the improved form of purified crystalline SNI may comprise other impurities within a body tolerance limit and complying with standard requirements.
• the improved form of purified crystalline sodium nitrite may comprise impurities in trace amounts.
• a water content may be no greater than about 0.5% by weight, wherein the heavy metal content is no greater than about 15 ppm.
• the form of sodium nitrite may contain no greater than about 0.05% by weight of chloride content, contain no greater than about 0.05% by weight of sulfate, contain no greater than about 0.002% by weight of iron, no greater than 0.0001 ppm of lead, no greater than 0.0001 ppm of Arsenic 0.9 ppm contain no greater than about 500 ppm of potassium, contain no greater than 0.0001 ppm of mercury and contain no greater than about 1 ppm of arsenic.
• the improved form of purified crystalline sodium nitrite is free of heavy metal such as Arsenic (As), Mercury (Hg), and lead (Pb).
• the heavy metal content in the sodium nitrite provided herein is determined according to Test-7 described in the examples. It has been surprisingly observed that by following a process as described below the improved form of purified crystalline sodium nitrite comprise no trace amounts of heavy metal such as Arsenic (As), Mercury (Hg), and lead (Pb).
• the form of sodium nitrite may comprise an amount of chloride ion impurity no more than 0.0092%.
• the amount of sodium nitrate in the sodium nitrite provided herein is determined by a spectrophotometry method as described in Test-5 below.
• the form of sodium nitrite may comprise an amount of chloride ion impurity no more than 0.0092%. In certain embodiments, the chloride content in the sodium nitrite provided herein is determined according to Method as described in Test-4 below. In yet another embodiment, the form of sodium nitrite may comprise an amount of ferric ion impurity no more than 0.001%. In certain embodiments, the ferric ion content in the sodium nitrite provided herein is determined according to Method as described in Test-6 below. In yet another embodiment, the form of sodium nitrite may comprise an amount of sulphate ion impurity no more than 0.032%, and an amount of Fluoride ion impurity is no more than 1 ppm.
• the sulphate ion content in the sodium nitrite provided herein is determined according to Method as described in standard protocols.
• the form of sodium nitrite may comprise an amount of sodium carbonate impurity is no greater than 0.1%.
• the sodium carbonate content in the sodium nitrite provided herein is determined according to Method as described in Test-3 below.
• the form of sodium nitrite may comprise a content of Copper is no greater than 0.15 ppm, a content of Zinc is no greater than 0.2, a content of cadmium is no greater than 0.1 ppm, a content of chromium is no greater than 0.1 ppm, a content of chromium is no greater than 0.1 ppm, a content of Manganese is no greater than 0.11 ppm, and a content of Nickel is no greater than 0.1 ppm.
• the form of sodium nitrite may be a coated form of sodium nitrite comprising an amount of an anti-caking agent no greater than 0.1%.
• the anticaking agent used for obtaining a coated improved form of purified crystalline SNI may be selected from but not limited to silicon dioxide, sodium silicate or sodium alkyl-naphthalene sulfonate, calcium silicate.
• a shape of improved form of purified crystalline SNI may be optimized as a modified crystalline granule form and a height of the improved form of purified crystalline SNI is between 5 to 6 mm and the width of the crystalline granule form is between 7 to 8 mm.
• a suitable process to obtain the disclosed improved form of purified crystalline sodium nitrite with minimum impurities is provided in Indian Application No.
• a process of obtaining an improved form of purified crystalline sodium nitrite is disclosed.
• the process may comprise a step of mixing a predetermined ratio of air and ammonia in a venturi body mixer.
• the process may comprise transmitting an air ammonia mixture from the venturi body mixer through a HEPA filter for filtering out impurities.
• the step of transmitting the air ammonia mixture through a HEPA filter may enable filtering our smaller impurities with a particle size of at least 0.3 ⁇ m to obtain a purified air-ammonia mixture.
• the purification of air-ammonia mixture using HEPA filter reduces the impurity content of primary ingredient such as air-ammonia mixture in the modified SNI production process.
• utilization of purified air-ammonia mixture for oxidation and to obtain oxides of nitrogen minimizes formation impurities other than sodium nitrate at very primary stage of production of improved form of purified crystalline SNI.
• the process may comprise a further step of introducing the purified air-ammonia mixture into the adiabatic burner at a temperature between 150°C-170°C.
• the adiabatic burner is characterized by having a conical geometry and a ratio of internal diameter to cone length in the order of 5:6.
• the process may further comprise transmitting the mixture of air-ammonia through a plurality of catalytic gauzes positioned as three pairs of two gauzes each at a temperature range between 850 °C- 950 °C and a pressure between 1-4 bar to carry out the selective oxidation process and to selectively obtain oxides of nitrogen.
• the process may further comprise a step of transferring the oxides of nitrogen to the waste heat recovery boiler (WHRB) to saturate and cool the oxides of nitrogen composition to a set temperature, wherein the temperature of the composition is reduced from 950°C up to 200 °C.
• the process may comprise passing a saturated oxides of nitrogen through one or more absorption towers and absorbing NO2 gas in one or more absorption towers containing an alkali medium for selective formation of sodium nitrite slurry.
• the process may comprise passing a saturated oxides of nitrogen through four absorption towers and absorbing NO 2 gas in the absorption towers containing an alkali medium for selective formation of sodium nitrite slurry.
• the improved form of purified crystalline sodium nitrite comprises no trace amounts of heavy metal such as Arsenic (As), Mercury (Hg), and lead (Pb).
• As Arsenic
• Hg Mercury
• Pb lead
• As the air-ammonia mixture is purified before oxidation and then a selective absorption of NO2 gas in absorption tower to obtain a crude crystalline form of SNI followed by recrystallization of a crude crystalline form of SNI using one or more solvents and more preferably water enables formation of the improved form of purified crystalline SNI with purity level greater than 99% and free of any trace amounts of harmful heavy metals.
• the process may comprise a further step of optimizing a concentration of sodium nitrite (SNI) slurry by heating the SNI slurry in a Crystallizer is carried out.
• a temperature inside the Crystallizer comprising slurry mass of sodium nitrite is maintained to a predefined temperature between 85-90°C under stirring at predefined stirrer speed and a predefined tip speed for a predefined period of time to obtain a concentrated SNI slurry mass.
• the process may comprise gradually cooling of the SNI slurry mass up to a predefined temperature adjusted between 45°C-40°C and reducing stirrer speed to a predefined value after completing a cooling cycle.
• the process may comprise a step of evaporating a hot liquor from the SNI slurry mass to obtain pure solids of SNI.
• the process may comprise crystallizing the pure solids of SNI to obtain a crude crystalline form of SNI.
• the process may also comprise an additional step of recrystallization of crude crystalline form of SNI by multiple washing of the crude crystalline form of SNI using one or more solvents and more preferably water for removing the impurities to obtain an optimized crystal form of SNI.
• the process may also comprise a step of drying the crystal form of SNI for specific amount of time to obtain the modified form of sodium nitrite.
• the process may further comprise a step of breaking and crushing lumps of the modified form of sodium nitrite and sieving through a predefined mesh structure to obtain a uniform and improved form of purified crystalline sodium nitrite.
• the method may comprise a step of adding anti-caking agent to the crude crystalline form of SNI to obtain a coated improved form of purified crystalline of SNI.
• the alkali medium in the absorption towers is selected from at least one but not limited Sodium carbonate, and sodium hydroxide.
• the improved form of purified crystalline sodium nitrite comprising one or more impurities may further be refined to obtain one or more different forms complying with shape, and purity and impurity standards such as: a purified form of SNI without an anti-caking agent (uncoated), a coated form of SNI with an anti-caking agent, in accordance with embodiments of the present disclosure.
• a purified form of SNI without an anti-caking agent uncoated
• a coated form of SNI with an anti-caking agent in accordance with embodiments of the present disclosure.
• Examples Form- I an improved form of purified crystalline SNI without using anti-caking agent (uncoated SNI) is disclosed herein. Further, the uncoated SNI crystal may comprise an optimized improved form of purified crystalline granule without any sharp edges. Such form of SNI becomes easy to handle during handling and transportation and does not form lumps.
• an improved form of purified crystalline SNI is a coated SNI with an anti- caking agent in an amount no greater than 0.09%.
• the coated SNI comprises anti-caking agent selected from, but not limited to, silicon dioxide, sodium silicate or sodium alkyl-naphthalene sulfonate, calcium silicate.
• Example 1 discloses a comparison of the impurity data of the uncoated improved form of purified crystalline SNI and an anti-caking agent coated improved form of purified crystalline SNI obtained by the method as described with the Indian standard grades of SNI in accordance with an embodiment of the present disclosure.
• Test-1 Purity testing Method of Sodium Nitrite
• a purity of all forms Sodium nitrite in Table 1 was tested using a following method: An amount of 3.16 gm KMnO 4 was dissolved in 100 ml D M water. The solution of KMnO 4 were then digested over a hot plate for one hour. The KMnO 4 solution was cooled filtered through Grade 4 sintered glass funnel without applying vacuum for 24 hours. After 24 hours KMnO 4 solution was diluted 1000 ml by demineralized water (DM) water. The solution was standardized same for exact normality of 0.1N.
• DM demineralized water
• Test-2 Loss on drying (LOD) of Sodium Nitrite
• LOD Loss on drying
• an amount of loss on drying of all forms Sodium nitrite in Table 1 was tested using a Mettler Toledo Halogen Moisture Analyzer Model-HG-53 and by following method: Following protocol was followed to test the LOD: Start the instrument, pre-heat the empty aluminium pan (foil) at temp+/-100°C for five minutes. Then take the quantity mansion in bellow table. Set the temperature & time as mentioned in below table. Press Start key and observe the final reading directly as % loss on drying.
• Test-3 Alkalinity by content of Na 2 CO 3 impurity in the forms of SNI
• an alkalinity content of all forms Sodium nitrite in Table 1 was tested using a following method: (a) Reagents used: 0.1 N H 2 SO 4 Solution; 0.1 N H 2 SO 4 is prepared by mixing 2.82 ml. of pure Sulphuric acid in water and dilute to 1000 ml by distilled water, standardize it. (b) 0.1% w/v Phenolphthalein indicator solution: Dissolve 0.1 gm of Phenolphthalein powder in 80 ml of 95% methanol and finally dilute to 100 ml with distilled water.
• % of content of Na 2 CO 3 impurity in the forms of SNI in the dry of sodium nitrite test sample was calculated as below:
• Test-4 Impurity content of Chloride as Cl
• a chloride content of all forms Sodium nitrite in Table 1 was tested using a following method: Reagents used: (a) Nitric acid pure (70% w/w) (b) Standard Silver Nitrate solution - 0.1 N: Dissolve 17 gm Silver Nitrate pure in DM water and dilute to 1000 ml in volumetric flask and Standardise it.
• % of content of Chloride (Cl) impurity in the forms of SNI in the dry of sodium nitrite test sample was calculated as below: Test-5: Impurity content of Sodium nitrate In one embodiment, an impurity content of sodium nitrate of all forms Sodium nitrite in Table 1 was tested using a following method: Reagents required: (a) Phenol Sulphonic acid reagent: Take 24 gm Phenol in Conical flask, add 12 ml distilled water, add 150 ml AR grade Con.H2SO4.
• % of content of Sodium Nitrate (NaNO 3 ) impurity in the forms of SNI in the dry of sodium nitrite test sample was calculated as below:
• Test-6 Impurity content of Iron as Fe3+
• an impurity content of Iron as Fe3+ of all forms Sodium nitrite in Table 1 was tested using a following method: Reagents used: (a) Hydrochloric acid pure 30% w/w (b) Sulphuric acid pure 98% w/w (c) 10% w/v Sulphuric acid: Take 10 ml Con H2SO4 and dilute to 100 ml very carefully by cold DM Water. Add H2SO4 slowly In cold D M water.
• Protocol Take 5gm of the Sample (suitable quantity) in glass evaporating dish and evaporate to dryness it on electric burner. Then cool it. Add 7 ml Sulphuric acid solution. Repeat the evaporation to dry the sample, cool the sample and add 2 ml Conc. HCl, add slight DM water, warm it, shake it, and filter the solution by 42. Filter paper in Nessler cylinder. Add 3 ml 30% Potassium thiocyanate solution, dilute to 50 ml by DM water. A blank experiment is carried out using 2 ml of Conc. HCL and 3 ml of 30% Potassium thiocyanate solution and dilute to 50 ml by DM water.
• Test-7 Impurity content of Heavy metal as Pb
• Protocol Take 10 gm sample (Suitable quantity) in glass dish add 25 ml D M water, dissolve it, add 25 ml concentrated hydrochloric acid and evaporate to dryness on water-bath until the odor of hydrochloric acid is no longer perceptible. Dissolve the residue in 30 ml DM water; transfer it to 100 ml Nessler cylinder. If solution is dark/black, then solution pass through activated carbon (Charcoal powder) & collect the clear colorless solution. In this clear color solution, add 2ml dil. Acetic acid & pass H2S gas for 1 minutes & dilute 50ml mark See the dark colour and compare it with standard colour of Lead.
• % of content of Lead as Pb impurity in the forms of SNI in the dry of sodium nitrite test sample was calculated as below: Test-8: Clarity of solution
• a clarity of sodium nitrate solution of all forms Sodium nitrite in Table 1 was tested using a following method: Prepare a solution in DM water as per specification concentration. Stir well up to dissolve the product, then warm and cool at room temperature. See the clarity of solution and note the observation.
• Example 2 In this Example 2, an additional metal content analysis in the SNI sample of the present invention was carried out.
• Table 2 discloses a comparison of the impurity data of the uncoated improved form of purified crystalline SNI and an anti-caking agent coated improved form of purified crystalline SNI obtained by the method as described with the standard grades of SNI in accordance with an embodiment of the present disclosure.
• the improved form of purified crystalline sodium nitrite (SNI) described above may have following advantages including but not limited to: •
• the highly pure sodium nitrite has purity no less than 99% •
• the highly pure sodium nitrite may be obtained in a specific uniform purified crystalline granule powder obtained by a modified method as described above •
• the modified pure form of sodium nitrite is free of heavy metals such as lead (Pb), Arsenic (As) and Mercury (Hg).
• Pb lead
• Hg Mercury

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