Hydrochloric acid regeneration

Hydrochloric acid regeneration or HCl regeneration refers to a chemical process for the reclamation of bound and unbound HCl from metal chloride solutions as hydrochloric acid.

Additional recommended knowledge

Weighing the right way

What is the Correct Way to Check Repeatability in Balances?

How to ensure accurate weighing results every day?

Field of application

The commercially most relevant field of application for HCl regeneration processes is the recovery of HCl from waste pickle liquors from carbon steel pickling lines. Other applications include the production of metal oxides such as, but not limited, to Al₂O₃ and MgO as well as rare earth oxides by pyrohydrolysis of aqueous metal chloride or rare earth chloride solutions.

A number of different process routes are available. The most widely used is based on pyrohydrolysis and adiabatic absorption of hydrogen chloride in water.

Known Processes

The following processes for the regeneration of HCl from spent pickle liquors have been adopted by the ferrous metals processing industry:

Regeneration

• Pyrohydrolysis
• Hydrothermal Regeneration
• Electrolytic Fe-precipitation

Recovery of free HCl

• Retardation
• Dialysis
• Ion Exchange

Transformation of FeCl2 to FeCl3

• Electrolytic Oxidation
• Chemical Oxidation

Pyrohydrolysis of Spent Pickle Liquor

Pyrohydrolysis of hydrochloric SPL from carbon steel pickling lines is a hydrometallurgical reaction which takes place according to the following chemical formulae:

4 FeCl₂ + 4 H₂O + O₂ = 8 HCl + 2 Fe₂O₃

2 FeCl₃ + 3 H₂O = 6 HCl + Fe₂O₃

The process is an inversion of the chemical descaling (pickling) process.

Main differences between different implementations of pyrohydrolytic acid regeneration

• Furnace Type (Spray Roaster, Fluidised Bed or Combined Furnace)
• Physical Properties of Iron Oxide By-Product (Ferric Oxide Powder or Pellets)
• Purity and commercial value of Iron Oxide By-Product (Cl content, SiO₂ content, other impurities, specific weight, specific surface)
• Energy Consumption (between 600 and 1200 kcal/l)
• Fuel Type
• Concentration of regenerated acid (typically approx. 18% wt/wt)
• Purity of regenerated acid (remaining Fe content, Cl content)
• Recovery Efficiency (typically 99%)
• Rinse Water Utilization
• Stack Emissions (HCl, Cl₂, Dust, CO, NOx)
• Liquid Effluents (composition, amount)

Basic Process Flow Diagram of Spray Roaster Hydrochloric Acid Regeneration Plant

Process Description of Spray Roaster Hydrochloric Acid Regeneration Plant

Preconcentration

The metal chloride solution (in the most common case waste pickle liquor from a carbon steel pickling line) is fed to the venturi evaporator (III), where direct mass and heat exchange with the hot roast gas from the roaster (reactor/cyclone) takes place. The separator (IV) separates the gas and liquid phase of the venturi evaporator product. The liquid phase is re-circulated back to the venturi evaporator to increase mass and heat exchange performance.

• approx. 25 to 30% of the waste acid (H₂O, HCl) are evaporated
• roast gas is cooled down to approx. 92 to 96 °C
• dust particles are removed from the roast gas

Roasting

Preconcentrated waste acid from the preconcentrator (III / IV) is injected into the reactor (I) by means of one or more spray booms (VIII) bearing one or more injection nozzles each. Injection takes place at reactor top at a pressure between 4 and 10 bar. The reactor is directly fired by tangentially mounted burners that create a hot swirl. Temperatures inside the reactor vary between 700 °C (burner level) and 370 °C (roast gas exit duct). In the reactor the conversion of droplets of preconcentrated waste acid into iron oxide powder and hydrogen chloride gas takes place. Hydrogen Chloride leaves the reactor through the top, while iron oxide powder is removed from the reactor bottom by means of mechanical extraction devices. A cyclone (II) in the roast gas duct ensures separation and feed back of larger oxide particles carried by the roast gas.

Absorption

In the absorption column (V) the hydrogen chloride compound of the saturated roast gas leaving the preconcentrator is adiabatically absorbed in water (which in many cases is acid rinse water from a carbon steel pickling line). Regenerated acid (typical strength: 18% wt/wt) is collected at absorption column bottom.

Exhaust Gas Treatment

The roast gas is conveyed through the system by means of an exhaust gas fan (VI). Fans in plants provide pressure increases of approx. 200 mbar and are feedback-controlled to maintain a relative pressure of -3 mbar between reactor and atmosphere to avoid any overpressure-related leakinge of acid gas. To rinse the impeller and cool the gas as well as to remove remaining traces of HCl from the roast gas, the exhaust gas fan is commonly supplied with quenching water, which is separated from the exhaust gas stream by means of a mist eliminator (VII) at the pressure side of the fan. In a final scrubber, commonly consisting of a combination of wet scrubbers such as venturi scrubbers (IX) and scrubber columns (X), remaining traces of HCl and dust are removed. In some plant, absorption chemicals such as NaOH and Na₂S₂O₃ are used to bind HCl and Cl₂ (which is created under certain circumstances in several, but not all spray roasting reactors).