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7/28/2019 Phosphorus Industry
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Chemical Process Technology
CHE C322
PHOSPHORUS INDUSTRY
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PRODUCTS OF PHOSPHORUS
INDUSTRY
The major source of phosphorus is from commercialdeposits of phosphate rocks in the mineral formFluorapatite [ Ca(PO4)6F2]
The products under the phosphorus industry are:
1. Phosphorus
2. Phosphoric acid
3. Ammonium phosphate
4. Calcium phosphate Fertilizers5. Nitro phosphate
6. Sodium phosphate
7. Organic phosphate
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Phosphorus (P4)
Types : Yellow phosphorus Red phosphorus Brown/black
Yellow phosphorus: Red phosphorusMol. Wt- 123.9 123.9
MP- 44.1 oC 593oC
BP- 280oCDensity: More dense (polymeric
material)
Solid- 1.82 2.36 gm/cc
Liquid-1.74 (45o
C)Ignites spontaneously, Formed by heating yellow- P
stored under waterDisagreeable odour Higher oxidation resistance and
Extremely toxic stability
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Uses of phosphorus :
Phosphorus is used to make H3PO4 acid, which is used to makephosphate fertilizers.
An alloy of P called phosphor-bronze is made from P, Cu andSn. This alloy has many applications as it is a stretchablemetallic material.
Red P is used to make match stick heads. The compound is asulphide of red P.
used to make smoke bombs used in wars.
used in fireworks.
Since it is poisonous, it is used for preparing chemicals with
zinc phosphide that kill domestic pests like rats. It is also used in the manufacture of P- tetra chloride or P-
penta chloride that are used as chlorinating agents inindustries.
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Method of production
Raw material :
Low grade crushed phosphate rock, coke as reductant, andsand as flux.
Chemical reactions:
a) 2Ca3(PO4)2 + 10C + 6SiO2 P4 + 6CaSiO3 + 10COBPL(Bone coke flux yellow
phosphate of lime) Phosphorus (+H = 680 kcal)
b) P4 P4yellow Phosphorus Red Phosphorus
** Red phosphorous, which is used in the manufacture of safety matches, can beconverted into white phosphorous by vaporization followed by condensation.
1400-1450 C
250-450 C
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Flow diagram- Phosphorus
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Process Description
Phosphate grinding and sintering (at 1200-1250 C)
BPL is sintered from sand particle size to marble size lumps
This step increases charge porosity to facilitate the release of P4 &CO vapors and decreases entrained dust.
Phosphate reduction in Electric furnace
Nodulized rock with silica, sand and coke is fed to phosphorusfurnace (200-300 V, AC-3 Phase ) which heat the charge to 1400-1450 C (sufficient to fuse it and initiate the fluxing and reducingreaction, which leads the P4 formation).
Separation and Purification
CO and P4 vapor mixture are fed to electrostatic precipitator whereentrained dust are removed when vapor are hot.
Next water spray condenser captures most of the liquid yellowphosphorous and separates it from non-condensible CO gas.
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Phosphoric Acid Via Phosphorus Combustion
One of the three routes for commercial production ofphosphoric acid.
The dry process also called combustion process.
The other two processes operate by acidulation of phosphate
rock with strong acids, and are referred as wet process.
Dry Process
It is obtained via combustion of yellow phosphorus in air
followed by hydration of phosphorus pentaoxide product withwater.
4P + 5 O2P4 O10 (H = -720 kcal)P4 O10 + 6 H2O 4 H3PO4 (H = -45 kcal)
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Process Description (Dry Process)
Direct contact of phosphorus vapor with an air streamand then passing the phosphorus pentaoxide produceddirectly into a hydrater.
The unconverted oxide plus phosphoric acid mist in the
exit gases from the absorption tower are capturedthrough an elctrostatic precipitator (demister). CO is alsovent off from upper section.
Purification of furnace acid is done by the addition of
sulfuric acid and silica. Impurities are precipitate out withsludge.
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Major engineering problem/issues
1.
Electric furnace design: Power is a major cost component of process
High voltage with large reaction zone, reduce electrodes used.
Fossil-fueled source of heat for rotary kiln combustion to provide
the energy of the endo-therm of the reaction.
2. Control and operation of furnace:
Changes in composition or ratio of blending of raw materialsmarkedly change the yield
3. Safety in handling phosphorus :
Molten phosphorous is shipped under water and inert gas.
Where elemental phosphorus must be used directly as in
incendiaries and matches, conversion to less poisonous redallotropic form with improved oxidation resistance is required.
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Phosphoric acid (H3PO4)Properties-
Mol. Wt-98MP- 42.4 C
BPLosses water of hydration at 213 C
Density1.83 gm / cc at 20 C
Completely miscible with waterIncompatibilities: Incompatible with powdered metals, strongbases, iron-containing compounds.
Method of production
1 Wet processa) Strong sulphuric acid leaching
b) HCl leaching
2. Electric furnace processes
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CONSUMTION PATTERN OF H3PO4
By far, largest use of phosphoricacid comes in the production offertilizers (>75%)
It is added to foods as a
preservative, acidifying agent, flavorenhancer, and clarifying agent
It is also used in processes such asthe coagulation of rubber latex,
electropolishing, soil stabilization,and as a catalyst in the productionof propylene and butene polymers,ethylbenzene, and cumene.
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Wet process (With H2SO4)
Chemical reactions:a) Ca3 (PO4) 2 +3 H2SO4 +6 H2O 2H3PO4 +3( CaSO4.2H2O) (H=-76.4kcal)
b) Side reactions:
CaF2 + H2SO4 + 2 H2O 2HF + CaSO4 . 2H2O
6HF + SiO2 H2SiF6 + 2H2O
Raw materials:
1. The high grade of imported ore is necessary to avoid solubilization of minedrock impurities such as aluminum, silicon, iron oxides.
A beneficiation process can be used on low grade ore which involves milling, screening,hydroseparation, classification and flotation.
2. Other raw material is strong sulfuric acid.
Gypsum
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Wet process ( H2SO4)
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Wet/IMI process (With HCl)
Chemical reaction:a) Ca3 (PO4)2 + 6 HCl + 6 H2O 2H3PO4 +3 CaCl2
b) Side reaction:
CaF2 +2 HCl 2HF + CaCl2
6HF + SiO2 H2SiF6 + 2H2O
Raw Materials:
1. Phosphate rock of high P2O5 content (>30%) is preferred to avoid excessiveacid consumption.
2. Hydrogen chloride gas or concentrated aqueous HCl (>30%) as waste or byproduct acid can be used.
3. Organic C4 and/or C5 alcohol solvents are used to extract H3PO4 fromCaCl2 solution.
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Wet process ( HCl)
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Major Engineering Issue
H2SO4 Leaching Process
1. Process design Fineness of grind
Undesired semihydrate andanhydrate at high T
Control of sulfuric acid
2. Material of construction Steel and lined with acid
proof brick Air vent PVC coated steel
Storage tank rubber linedsteel
HCl Leaching Process
1. Solvent recovery Relatively expensive solvent
Efficient solvent handling
2. Material of constructions HCl resistance
PVC lined rubber linedimpervious grafite
3. Waste disposal CaCl2 aq effleunt
Siliceous rock residue
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Process Comparison
The product acid from wet process using HCl is purerthan sulfuric acid acidulation process, and in additionthis process claimed to recover 98-99 % of the availableP2O5 in the rock, as opposed to experience of themost efficient sulfuric acid processes.
Trade hydrochloric acid is normally 2-3 times the priceof sulfuric acid.
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Phosphate Fertilizers
11 February 2012
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Synthetic Fertilizers
Plant growth is required a total of nine major nutrients to proceednormally. Three of these, C,H and O are obtained from air and soil(as water).
Another three Ca, Mg and S are present to a sufficient extent in mostordinary soils.
And another three N, P and K are present to a small extent but rapidlydepleted from the soil with plant removal for harvesting.
Nitrogen contributes to early plant development and greening; Phosphorusassists with early growth and seed or fruit development; Potassium is usedby plant for the production of cellulose and starches.
For the fertilizer analysis the three principal ingredients are specifiedin order as follow: nitrogen as %N, phosphorus as P2O5, and potassium K2O as three number
in sequence separated by hyphens.
Example: 0-20-20; 3-12-12; 5-20-20.
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Formulation of Major Active Constitutes
Major NutrientsAmmonia solutions, Urea, Superphosphates, Mixed fertilizers,bio fertilizers
Fillers and Conditioners
Fillers can include sand, gypsum, rock and assist in even distributionof fertilizers.
Conditioners are used to improve soil structure. Examples are sand,specially processed wood waste , synthetic polymer (Krylium).
Coated Fertilizer
A variety of coatings have been applied to fertilizer particles tocontrol their solubility in soil. Controlling the rate of nutrientrelease can offer multiple environmental, economic, and yieldbenefits.
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Calcium Phosphates
Finely ground phosphate rock (Ca3
(PO4
)2
) is occasionallyadded to fertilizer formulations as a diluent or filler. Howeverbecause phosphate rock has limited water solubility its actionas a phosphate nutrient is small and slow.
Hence a more soluble form of phosphate (SSP and TSP) are
made by the acidulation of phosphate rock. Generally known as Superphosphates.
Two distinct grade
Single SuperphosphatePhosphate rock + Sulfuric acid
P2O5 : 16-20 % Triple Superphosphate Phosphate rock + Phosphoric acid
P2O5 : 42-50 %
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Superphosphate
Raw Materials
Natural or beneficiated phosphate rock Dilute sulfuric acid (62- 70 % H2SO4)
Acidulation[Ca3 (PO4)2] 3. Ca F2 + 7H2SO4 (aq) 3CaH4 (PO4)2 .7Ca SO4 + 2HF
The product super phosphate contains the inert gypsum component as well as active
calcium dihydrogen phosphate. SiO2 impurity removal4HF + SiO2 SiF4 + 2H2O
3SiF4 + 2H2O 2H2SiF6 + SiO2
H2SiF6 + 2NaCl Na2SiF6 +2HCl
Process steps Mixing : Ground phosphate rock + Diluted H2SO4
Aging of superphosphate in Den
Granulation in rotary drum-granulator
Drying and Bagging
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Triple superphosphate
Much more concentrated than the ordinarysuperphosphate (45- 46 % of available P2O5).
Triple superphosphate is manufactured by the action of
phosphoric acid on phosphate rock.
CaF2. 3Ca3 (PO4)2 + 14H3PO4 10Ca (H2PO4)2 + 2HF
(Phosphate Rock) (Triple Superphosphate)
Process : Very similar to SSP.
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Engineering Problem
Sources of particulate emissions : reactor, granulator, dryer, screens, cooler,
mills, transfer conveyors.Fluorine compounds and dust particles: Silicon tetrafluoride (SiF4) andhydrogen fluoride (HF) a evolve from the reactors, den, granulator, and dryer.
Bag houses : to control the fine rock particles generated by the rock
grinding and handlingCyclonic scrubbers: scrubbing the effluent gas emissions from the reactor,den, and granulatorGaseous SiF4 in the presence of moisture reacts to form gelatinous silica,which has the tendency to plug scrubber packings.
use of conventional packed countercurrent scrubbers other contacting devices with small gas passages for emissions controlis not feasible.Scrubber types that can be used are: (1) spray tower, (2) cyclone, (3)venturi, (4) impingement, (5) jet ejector, and (6) spray-crossflow packed.
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Ammonium Phosphate
Mono-ammonium phosphate
Reaction Involve
Reacting ammonia withphosphoric acid, centrifuging anddrying in a rotary dryer.
NH3 + H3PO4 NH4H2PO4
Ammonia to phosphoric acidratio is 0.6 in the pre-neutralizer and then 1.0 in thegranulator
Di-ammonium phosphate.
Reaction Involve
A two-stage reactor system inorder to prevent loss of ammonia.
NH3 + H3PO4 NH4H2PO4
NH3 + NH4H2PO4 (NH4)2HPO4
The ratios are 1.4 and 1.0 in thepre-neutralizer and granulatorrespectively
Two types of Ammonium phosphate
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Process description
Neutralization
Phosphoric acid and sulfuric acid, added to 3 continuous mixedreactors.
Anhydrous ammonia is added in first neutralizer
Granulation Slurry from third neutralizer is mixed with KCl and feed to
rotating drum granulator
Rotary adiabatic drier removes the moisture < 1%
Screening Dried product is separated into three fractions.
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Nitrophosphates
Mixtures of ammonium nitrate and various phosphates made
by acidulation of phosphate rock with HNO3 and/or H2SO4
Chemical Reactions:
Nitric Acid Digestion- Ammonia NeutralizationCa3(PO4)2 +6HNO3+4NH3 Ca(NO3)2+2CaHPO4+4NH4NO3
Nitric Acid-Sulfuric acid Digestion- Ammonia Neutralization
Ca3(PO4)2 +6HNO3+6NH3 + H2SO4 2CaHPO4 + 6NH4NO3 +CaSO4
Conversion to monocalcium phosphate
2CaHPO4 + H2SO4 Ca(H2PO4 )2 + CaSO4
Carbonitric Process
Ca3 (PO4)2 +6HNO3+6NH3 + CO2+ H2O 2CaHPO4+ 6NH4NO3+ CaCO3
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Process description
Pulverized phosphate rock is digested with nitric (ormixed acid)
Similar to wet process (Phosphoric acid)
Acid strength 25-40 % HNO3
Digested slurry is pumped to an ammoniating tank
Here chemical reaction completes
Granulation and drying
In rotary equipments Followed by screening in classifying circuit
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Major Engineering Problems
Removal of Calcium nitrate
Ca(NO3) is highly hygroscopic (product to lump)
For HNO3 (reaction 1) : digested liquor must be chilled to removecalcium nitrate crystals
Mixed acid process (reaction 2)or carbonitric process (reaction 3) :
conversion to CaSO4 or CaCO3
Corrosion
Corrosion of digestion and neutralization equipment byHNO3 : 18-8 stainless steel.
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SODIUM PHOSPHATE
Numerous combinations of Na with P and O exist, e.g.Sodium Meta, Poly, Ortho, Pyro Phosphate.
Ortho- and polyphosphate are made from varying ratio ofcarbonate, sodium hydroxides and orthophosphoric acid.
The principal use of alkali phosphates is in detergentformulation. Other applications include metal cleaning,boiler water treatment, in foodstuffs.
Sodium tripolyphosphate, STPP, Na5P3O10, is the mainphosphate present in detergents.
S di T i l h h t (STTP)
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Sodium Tripolyphosphate (STTP)
Overall reaction 5 Na2CO3 + 6 H3PO4 2Na5P3O10 + 9 H2O + 5CO2
It is prepared from phosphoric acid by neutralisation withsoda ash (sodium oxide) forming sodium hydrogenphosphates. A powdered mixture of disodium hydrogen phosphate, and
sodium dihydrogen phosphate is heated to 500C to 550C toproduce the stable form of STPP
2 Na2HPO4 + NaH2PO4 Na5P3O10 + 2 H2O In a single-stage process the orthophosphate solution is
converted from a liquid phase in one process step to becomemarketable STPP in its solid free-flowing form. The single stageprocess uses a rotary kiln in which granulation, drying,polycondensation and calcination of the ortho -phosphatesolution to finished STPP take place in a single step.
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Process Flow Sheet