A method for removing thallium in waste water
A technology for wastewater and solution, applied in chemical instruments and methods, water pollutants, water/sewage treatment, etc., can solve the problems of low efficiency, insufficient thallium removal depth, and inability to use thallium-containing wastewater treatment process, and achieve the thallium removal process. Simple, low-cost thallium removal
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Embodiment 1
[0015] The pickling wastewater from a sulfuric acid plant contains 45 micrograms per liter of thallium, and its treatment process is as follows:.
[0016] (1) Add 20ml / L of 10% sodium sulfite solution to the wastewater, adjust the pH value to 6.5, and stir thoroughly for half an hour.
[0017] (2) Potassium ferrocyanide solution and excess ferric chloride solution are fully mixed to obtain a mixture of Prussian blue, ferric chloride and water, and then this mixture is added to the above waste water to control potassium ferrocyanide The amount added to the waste water is 0.3 mg / L, and it is fully stirred for 15 minutes.
[0018] (3) Add 3ml / L of 10% ferric chloride solution and stir for 15 minutes.
[0019] (4) Solid-liquid separation to remove thallium from wastewater.
[0020] The waste water is treated according to the above-mentioned steps of thallium removal, and the removal rate of thallium reaches 98%.
Embodiment 2
[0022] The thallium content of wastewater from a zinc smelter is 1056 micrograms per liter, and the treatment process is as follows:
[0023] (1) Add 30ml / L of 10% sodium sulfite solution to the wastewater, adjust the pH value to 6.8, and stir thoroughly for half an hour.
[0024] (2) Potassium ferrocyanide solution and excess ferric chloride solution are fully mixed to obtain a mixture of Prussian blue, ferric chloride and water, and then this mixture is added to the above waste water to control potassium ferrocyanide The amount added to the waste water is 6 mg / L, and it is fully stirred for 15 minutes.
[0025] (3) Add 10ml / L of 10% ferric sulfate solution and stir for 15 minutes.
[0026] (4) Solid-liquid separation to remove thallium from wastewater.
[0027] According to the above-mentioned thallium removal steps to treat the wastewater, the removal rate of thallium reaches 99.5%.
Embodiment 3
[0029] The thallium content of desulfurization wastewater from a steelmaking plant is 6,700 micrograms per liter, and the treatment process is as follows:
[0030] (1) Add 50ml / L of 10% sodium sulfite solution to the wastewater, adjust the pH value to 7.2, and stir thoroughly for half an hour.
[0031] (2) Potassium ferrocyanide solution and excess ferric chloride solution are fully mixed to obtain a mixture of Prussian blue, ferric chloride and water, and then this mixture is added to the above waste water to control potassium ferrocyanide The addition amount in the waste water is 38 mg / liter, fully stirred for half an hour.
[0032] (3) Add 30ml / L of 10% polyferric sulfate solution and stir thoroughly for half an hour.
[0033] (4) Solid-liquid separation to remove thallium from wastewater.
[0034] According to the above-mentioned thallium removal steps to treat the wastewater, the removal rate of thallium reaches 99.9%.
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