RU2750044C2 - Sulphuric-alkaline waste purification unit (variants) - Google Patents

Abstract

FIELD: separation.SUBSTANCE: invention relates to sulphuric-alkaline waste purification units. Proposed are two variants of the unit including two carbonisation columns, an oxidising reactor with a cooling unit, an apparatus with a submerged burner, a recuperative heat exchanger, three refrigerators and a separation apparatus. During operation of the unit according to the first variant, sulphuric-alkaline wastewater is supplied to the first carbonisation column wherein light sulphuric compounds are blown off by a part of the flue gas supplied from the apparatus with a submerged burner. The produced sulphur dioxide together with the exhaust air and fuel are supplied to the burner. Carbonised wastewater is removed from the first carbonisation column, heated in the recuperative heat exchanger, and sent together with air to the bottom of the reactor wherein sulphuric compounds are oxidised in the presence of a heterogeneous catalyst. The oxidised wastewater is removed from the top of the reactor, cooled in the first refrigerator and separated in the separation apparatus into exhaust air and oxidised wastewater supplied to the apparatus with a submerged burner wherefrom the heated oxidised wastewater is removed, cooled in the recuperative heat exchanger, mixed with a circulating cooling agent after the cooling unit, cooled in the second refrigerator and supplied to the upper part of the second carbonisation column into the lower part whereof the remaining flue gas is supplied after being cooled in the third refrigerator. Exhaust gas is removed from the top and purified wastewater is removed from the bottom of the second carbonisation column, wherein some of the wastewater is supplied to the cooling unit as a circulating cooling agent. Operation of the unit according to the second variant is characterised by sulphur dioxide and air being supplied to the burner.EFFECT: technical result is nonchemical and waste-free purification of sulphuric-alkaline wastewater.2 cl, 2 dwg

Description

The invention relates to installations for the purification of sulfur-alkaline effluents generated during alkaline purification of oil products, oil refining and in other industries.

Known installation used in the method of neutralization of sulfide-alkaline effluents [RU 2587437, publ. 06/20/2016, IPC C02F 1/72, C10G 53/14, C10G 27/12], containing a mechanical filter, a volumetric flow meter, a dosing pump, a mixing unit with industrial water, a tubular reactor for catalytic oxidation with an aqueous solution of hydrogen peroxide in the presence of homogeneous catalyst and tank reactor.

The disadvantages of the known installation are the contamination of effluents with a catalyst and the use of an expensive explosive reagent, hydrogen peroxide, as an oxidizer.

The closest in technical essence is a method for the purification of sulfide-alkaline effluents [RU 2460692, publ. 09/10/2012, IPC C02F 1/24, C02F 9/14, B01D 3/38, C02F 103/18], carried out on a plant that includes a waste heat exchanger, waste mixers with carbon dioxide and sulfuric acid and stripping (desorption) a column equipped with a sour gas outlet line with a refrigerator and a separator.

The disadvantages of this installation are the use of water vapor and reagents (carbon dioxide and sulfuric acid), as well as the production of waste - sulfur dioxide, requiring further disposal.

The objective of the present invention is reagent-free and waste-free purification of sulphurous-alkaline effluents.

The technical result is reagent-free and waste-free purification of alkaline sulphide waste by equipping the installation with a reactor with a heterogeneous oxidation catalyst, as well as an apparatus with a submerged burner as a source of carbon dioxide.

Two installation options are offered. The technical result in the first embodiment is achieved by the fact that in the proposed installation, which includes a heat exchanger and a stripping column with lines for supplying effluents and removing sour gas, the peculiarity is that the first carbonization column is installed as a stripping column, and the unit is equipped with an apparatus with a submerged burner equipped with oxidized waste inlet and outlet lines, flue gas outlet, fuel supply and an exhaust air supply line connected to the sour gas outlet line from the first carbonization column, which is equipped with a sulphurous-alkaline waste water inlet line and connected to a carbonated wastewater supply line, on which a heat exchanger is located, with the bottom of the reactor with a heterogeneous oxidation catalyst and a cooling unit, and is also connected to the flue gas outlet line, while the lower part of the reactor is equipped with an air supply line, and the upper part with an oxidation products outlet line, on which the first cooler and a separation device equipped with an exhaust air supply line and connected to an apparatus with a submersible burner by an oxidized waste inlet line, in addition, a heat exchanger is located on the oxidized waste outlet line, an adjoining circulating purified waste supply line after the cooling unit, a second cooler and a second carbonization column connected to a flue gas outlet line a supply line of its part, equipped with a third cooler, and equipped with an exhaust gas outlet line and a treated wastewater outlet line, which is connected to the cooling unit by a circulating treated wastewater supply line. The second variant of the installation is distinguished by the connection of the burner to the sour gas outlet line and to the air supply line.

The unit can be equipped with a device for preliminary treatment of wastewater from mechanical impurities and oil products, an afterburner of waste gases, a wastewater treatment unit (for example, a filter), an oxidation promoter circulation system, which is fed into the stream of carbonated wastewater in front of the reactor and is separated in a separation device, as well as a line air supply with a lack of oxygen to ensure stable fuel combustion in an apparatus with a submersible burner (in the first version).

The oxidation reactor contains a heterogeneous catalyst for the oxidation of sulfur compounds. Columns of carbonization can be equipped with packed or poppet contact devices, and the burner can be made in the form of a device for catalytic oxidation or fiery combustion of fuel. The separation device can be manufactured, for example, in the form of a two- or three-phase separator. Refrigerators can be made in the form of air or water coolers. The rest of the installation elements can be any device for the corresponding purpose known from the prior art.

Equipping the unit with a reactor with a heterogeneous oxidation catalyst allows the oxidation of hydrosulfide, sulfide ions and mercaptides of alkali metals to non-toxic compounds with atmospheric oxygen, thereby providing reagent-free and waste-free treatment of sulfur-alkaline effluents, and equipment of the unit with an apparatus with a submersible burner makes it possible to obtain carbon dioxide for primary carbonization of effluents, carried out in the first carbonization column to obtain sulfur dioxide, then sent to combustion, and for secondary carbonization of effluents, carried out in the second carbonization column in order to neutralize alkaline effluents with a decrease in pH to 6.5-8.5.

The proposed installation in both versions includes carbonation columns 1 and 2, a reactor 3 with a cooling unit, an apparatus 4 with a submerged burner 5, a heat exchanger 6, refrigerators 7-9 and a separator 10. The dotted line shows the possible equipment of the installation with a device for preliminary wastewater treatment 11, an afterburner 12, a post-treatment unit 13, feed lines of an oxidation promoter 14 and air 15. During the operation of the first version of the installation (Fig. 1), sulfur-alkaline effluents are fed through line 16 to column 1, where primary carbonization of effluents is carried out, blowing off light sulfur compounds with part of the flue gas supplied through line 17 from apparatus 4. Stripped gas is fed through line 18 to exhaust air supply line 19 or directly to burner 5 (not shown), to which fuel is supplied through line 20. Carbonated effluents are removed from column 1 through line 21, heated to the temperature of catalytic oxidation in heat exchanger 6 and sent to the bottom of reactor 3 together with air supplied through line 22. In reactor 3, in the presence of a heterogeneous catalyst, oxidation of sulfur compounds that have not been removed in column 1 occurs with obtaining non-toxic substances. Oxidized wastewater from the top of the reactor 3 is removed through line 23, cooled in refrigerator 7 and separated in separator 10 into exhaust air, which is removed through line 19 and oxidized wastewater supplied through line 24 to apparatus 4. Heated oxidized wastewater discharged from apparatus 4 along lines 25 are cooled in heat exchanger 6, mixed with the circulating part of the treated effluent supplied through line 26, cooled in cooler 8 and fed for re-carbonization to column 2, into which, after cooling in cooler 9, the remainder of the flue gas is fed through line 27. Exhaust gas is discharged from column 2 through line 28, and purified effluents are discharged through line 29, some of which are directed through line 26 as a circulating refrigerant to the cooling unit of reactor 3. The operation of the second embodiment (Fig. 2) is characterized in that exhaust air is discharged through line 19 from separator 10, and the stripped gas through line 18 is fed directly to the burner together with air supplied through line 15. The dotted line shows a possible preliminary purification of alkaline sulphide waste in device 11 from mechanical impurities and oil products discharged through lines 30, afterburning of waste gases in furnace 12, post-treatment of effluents in unit 13, supply of a circulating oxidation promoter through line 14 to line 21, and replenishment of air through line 15 in option 1.

Thus, the proposed installation allows for reagent-free and waste-free purification of sulfur-alkaline effluents and can be used in industry.

Claims (2)

1. Sulfur-alkaline effluent treatment unit, including the first carbonization column with a sulfur dioxide gas outlet and a heat exchanger, while the unit is equipped with an apparatus with a submerged burner equipped with oxidized waste inlet and outlet lines, flue gas outlet, fuel supply and exhaust air supply line, connected to the sulphurous gas outlet line from the first carbonization column, which is equipped with a sulfur-alkaline waste water inlet line and is connected to a carbonated waste water supply line, on which a heat exchanger is located, to the bottom of the reactor with a heterogeneous oxidation catalyst and a cooling unit, and is also connected to a flue gas outlet line , while the lower part of the reactor is equipped with an air supply line, and the upper part with an oxidation products outlet line, on which the first cooler and a separation device are located, equipped with an exhaust air supply line and connected by an oxidized waste inlet line to the apparatus with a submersible burner, in addition, on the line in The oxidized effluent outlet includes a heat exchanger, adjacent to the circulating treated effluent supply line after the cooling unit, a second cooler and a second carbonization column connected to the flue gas outlet line by a part supply line, equipped with a third cooler, and equipped with an flue gas outlet line and a treated effluent outlet line, which is connected to the cooling unit by a circulating treated wastewater supply line. 2. Unit for the treatment of sulphurous-alkaline wastewater, including the first carbonization column with a sulfur dioxide outlet line and a heat exchanger, while the unit is equipped with an apparatus with a submersible burner equipped with lines for the inlet and outlet of oxidized wastewater, flue gas outlet, fuel supply, air supply connected to sour gas outlet line from the first carbonization column, which is equipped with a sulfur-alkaline waste water inlet line and is connected by a carbonated waste water supply line, on which a heat exchanger is located, to the bottom of the reactor with a heterogeneous oxidation catalyst and a cooling unit, and is also connected to a flue gas outlet line, when In this case, the lower part of the reactor is equipped with an air supply line, and the upper part with an oxidation products outlet line, on which the first cooler and a separation device are located, equipped with an exhaust air outlet line and connected by an oxidized waste inlet line with an apparatus with a submersible burner, in addition, on the oxidized runoff a heat exchanger is located, an adjoining line for the supply of circulating treated effluents after the cooling unit, a second cooler and a second carbonization column connected to the flue gas outlet line by a supply line of its part equipped with a third cooler, and equipped with a flue gas outlet line and a treated effluent outlet line, which is connected with a cooling unit with a line for supplying circulating treated effluents.

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