SE450553B - PROCEDURE FOR WASHING SULFUR Dioxide FROM A GAS CURRENT IN A LARGE COOLING DEVICE WITH TWO CIRCUITS WITH WATER SLAYER - Google Patents

Description

The invention thus relates to a process for washing sulfur dioxide from a gas stream in a quenching washing device with two circuits with water slurry, wherein (a) quenching of the gas stream is carried out in a first cycle in a quencher with a first water slurry containing an alkaline agent consisting of lime, limestone or a mixture thereof and (b) the liquid from the quencher is transferred to a quench tank, which is characterized by (c) washing the quenched gas stream in a second circuit with a second water slurry isolated from the first the water slurry and containing an alkaline agent consisting of lime, limestone or a mixture thereof, in a sulfur dioxide absorber, (d) regulation of recycled water and selective use of streams with high and low solids content from a separator by (1) separating the water slurry effluent from the sulfur dioxide absorber into a low solids upper stream shalt and a high solids lower stream in a liquid and solid concentrator, (2) transferring the high solids moiety from the wash slurry to the quench tank, (3) cone; continuous dewatering of a part of the slurry from the quench tank and (4) removal of dry matter obtained in the dewatering step and return of the water thus obtained to the quench tank.

The two-cycle process insulates the main absorption system, including the mist separators, which are exposed to deposits and corrosion, from the quench part of the process, from which steam emits. All returned water is led to the evaporative cooling circuit and nothing to the circuit, which contains the mist separators and the primary absorption sections. However, at varying SO2 feed rates, the water returned to the cooling circuit may be either in excess or insufficient for the evaporative material balance in the quench circuit. To compensate for the imbalance in either direction, it is necessary to use a separation and flow regulator between the two circuits to reduce or increase the water flow to the quench circuit while maintaining the absorption circuit at the correct operating balance. Normally, the composition of the slurry should be controlled so that more than 3% of reaction products of combined calcium sulphite and calcium sulphate are allowed in the cooling circuit. Furthermore, in order to obtain an efficient absorption of sulfur dioxide, the calcium base should be maintained above a minimum level. Typically, an absorber with 450,553 operates between 6 and 14% solids content.

The two circuits then allow operation of the mist separators and the primary absorber parts in a completely open circuit, whereby contaminated recycled water is avoided and the use of additional mist separator wash water is maximized. The elimination of recycled water in these parts reduces incrustations, scale formation and uncontrolled crystallization, which prevent continuous operation of the SO2 washing system. This also allows the use of less expensive materials, which would otherwise be required to prevent attack by dissolved chemicals, such as chlorides.

The use of returned water from the drainage system in the second cycle, ie the quench part, means that the entire system can be run in a closed cycle, so that all available water is used in the process instead of disappearing.

The invention is described in more detail below in connection with the accompanying drawing, in which fig. Fig. 1 is a simplified flow chart of the system and Fig. 2 shows a partially sectioned, schematic view of a multi-stage cooling absorption tower, which can be used for carrying out the system according to the invention.

Referring to Fig. 1 of the drawing, 10 generally denotes a system according to the invention, and this system comprises a multi-stage quenching absorption tower 12, which is described in more detail in connection with Fig. 2, and comprises a quenching vessel 14 and an abutment. sorbator 16.

Arrows 18a, b and c denote the gas flow to the condenser 14, the gas flow from the condenser 14 to the absorber 16 resp. SO2 purified combustion gas from the absorber 16.

Other primary components of the system are the absorption tank 20, the bulk cooling fan 22, the drainage system 24, an absorption separator 26, pumps 28, 30 and 32, each with a water inlet designated by 34a, b and c for the pumps 32, 30 and 28, respectively.

The primary liquid / slurry lines for the system are: line 36 from the absorption tank 20 to the pump 28, line 38, which constitutes the primary absorption supply line from the pump 28 to the absorber 16, the secondary absorption supply line 40 from the absorption tank 20 to the pump 30, the the secondary absorption supply line 42 from the pump 30 to the absorber 16, the line 44 comprising a branch line 42 from the secondary absorption supply to the absorption separator 26, the line 46 from the absorber 16 to the absorption tank 20, the mist separator-wash water line 48 for the multi-stage cooling absorption tower 12, the line 50 which is the reagent supply line for the absorption tank 20, the discharge line 52 from the absorption separator 26 to the absorption tank 20, the discharge line 54 from the absorption separator 26, the overflow line 56 of the absorption tank 20 to the bulk cooling tank 22, the line 58 from the bulk cooling tank 22 to the pump 32, the line 60 the cooling supply line from the pump 32 to the quench 14, the return line 62 from the quench 14 to the quench tank 22, the line 64 comprising the outlet from the quench tank 22 to the dewatering system 24, the line 66 from the dewatering system 24 to the quench tank 22 and the line 68 comprising dewatering drain .

Referring to Fig. 2, the quench absorption tower 12 has a vertically disposed jacket 70, with a combustion gas inlet 72 at the lower end and an outlet 73 at the upper end for SO 2 -free combustion gas. Below the combustion gas inlet 72 is arranged a sump or quench cooling tank 22 provided with a stirring mechanism designated 76.

In Fig. 2, the quench section is denoted by 14 and the absorption section by 16. The quench section comprises a plurality of manifolds 80, which are intended to be connected to the line 60 from the pump 32 and each of the manifolds being provided with a plurality of spray nozzles 82. In a preferred embodiment, the cyclone-type quench section 14 with the combustion gases flowing through the inlet 72 and tangentially upward. The treatment liquid from the manifolds 80 flows through gravity down to the quench tank 22 and to the conduit 62, which is also depicted in Fig. 1.

Arranged between the bulk cooling section 14 and the absorption section 16 is a gas / liquid separator generally designated 84. This separator 84 collects the water from the mist separators and the slurry fluid from the absorber and the collected fluid is diverted from the separator 84. for return to the absorption tank via the line 46. Above the separator 84 are arranged a plurality of manifolds denoted by 86 and 86a each with connection to the lines 38 and 42, which constitute the primary and secondary absorption feed lines.

Each of the manifolds 86 and 86a is provided with a plurality of spray nozzles 88 and between the manifolds 86 and 86a a conventional tower gasket 90 is arranged. Above the manifold 86a a lower mist separator 92 and an upper mist separator 94 are arranged. the lower mist separator is supplied via the manifold 96 with a spray outlet 98. The upper mist separator 94 is also provided with a wash water supply device with a manifold 100 provided with spray nozzles 102. The absorber separator 26 and the dewatering system 24 in Fig. 1 may have the shape of hydrocyls. , thickeners, centrifuges or vacuum filters. Again referring to the drawings illustrating the present invention, the system comprises two circuits, a liquid circuit A, in which substantially all water losses occur by evaporation, and an absorber circuit B, comprising the mist separators 92 and 94, the gases first passing through the cooling circuit and then through the absorption circuit. The reactant stream goes countercurrent to the gas flow and first passes through the absorption circuit.

Solid particles are removed from the system as follows: solid products from the reaction between the calcium-based reactant and sulfur dioxide as well as unreacted reactant are fed from the absorption tank in the absorption circuit B to the cooling circuit A together with a certain amount of water through line 56 at substantially constant concentration. Slurry is also fed to cycle A through line 44, absorption separator 26 and line 54. The solid particles are then circulated through cooling circuit A, where more reaction products are formed as the concentration of reacted reactant decreases. The solid particles are then discharged from the condenser to the dewatering system 24 and finally to the landfill.

Supplementary water enters the absorption cycle as (1) water that comes with the reactant at 50, (2) smaller amounts of water from the 450 553 packing rings in the slurry pumps at 34c and b, and (3) mist separator wash water at 48. Supplemental water enters the cooling cycle as (1) ) small amounts of fresh make-up water from slurry pump and agitator packing rings at 34a resp. d, (2) condenser supplementation water (recycled water) at 66, which compensates for most of the evaporation losses, and (3) water which accompanies the solid particles discharged from the absorption cycle at 56 '.

When the process's need for supplemental water for the condenser is satisfied through recycled water generated by the slurry dewatering system and the discharge from the absorption circuit, optimal water utilization has been achieved.

When the recycled water formed exceeds the need for supplemental water for the condenser, the concentration of solid particles in the slurry discharged from the absorption loop must be increased. This is accomplished by standard control devices at the absorption separator 26, which cause a high solids stream in the range of 10-50% to flow through line 54 to mix with the slurry flowing through line 56, while a low solids stream in the range 3- 10% is returned to the absorption tank 20. The absorption circuit then operates as an open system, which discharges a slurry with a high solids content to the cooling circuit. Of course, the two circuits together form a closed system.

For those process conditions where the recycled water formed is less than the need for supplemental water for the condenser, it is desirable to increase the water content or decrease the solids content of the absorber discharge by controlling a low solids stream from the separator 26 for mixing with the discharged slurry in the line. S6 'from the absorber. At the same time, water can be supplied to the absorption circuit as mist separator wash water in relation to the total need for fresh make-up water.

As described above, it is necessary to vary the amount of water which emits together with the discharged solid particles from the absorption circuit, i.e. the concentration in the discharged slurry, without affecting the amount of solid particles and the chemical balance in the absorption circuit. This is done by using the separate: Myf '450 553 rator device 26 for solid and liquid materials and control devices, which are commercially available. This device treats part of the slurry of the absorption circuit to form two streams, one with a high solids content and one with a low solids content.

Either or both of these streams may be combined through one or more conduits 54 with an appropriate amount of untreated slurry 56 from the absorption circuit to provide a stream 56 'containing the desired concentration of slurry flowing into the quench tank 22. In this manner, a wide range of solids concentrations are achieved in the stream from the absorption outlet.

Since the plant's operating conditions, ie load factor and SO2 gas content, always vary, the rate of formation of solid particles in the absorption circuit and the amount of water needed in the inlet to the quench circuit will also vary. In order to enable the absorption system to react to the process' requirements for water in relation to solid particles in the slurry, a process signal is used. This signal inserts the SO2 mass flow into the absorption tower, the density of the absorption slurry or any other process variable, which changes with changed SO2 mass flow to the absorption tower in connection with the desired concentration in discharged slurry from the absorption circuit to the bulk cooling tank. The signal is fed to a control device (not shown), which maintains the concentration of solid particles in the output to the quench tank at the desired level.

Claims (3)

450 553 Claim 1. A process for washing sulfur dioxide from a gas stream in a quench-wash device (12) with two circuits with water slurry. wherein (8) (b) (C) (Ö) 2. A method according to claim 1. cycle in a condenser (14) down a first water slurry within a water aixalisxt neaei consisting of lime. limestone or a mixture thereof: and the liquid from the condenser (14) is transferred to a condensate tank (22). quenching of the gas stream is carried out in a first feature of washing the quenched gas stream (18b) in a second cycle with a second water slurry, son isolated from the first water slurry and son containing an alkaline agent consisting of lime, limestone or a mixture thereof. in a sulfur dioxide absorber (16): regulation of recycled water and selective use of currents with high and low solids content from a separator (26) by 1. separating the water slurry radiating from the sulfur dioxide absorber into an upper stream: a low solids content and a low solids lower stream in a liquid and solid concentrator; 2. transferring the high solids portion from the wash slurry to the quench tank (22): 3. continuous dewatering (24) of a portion of the slurry - from the quench tank; and - 4. removal of dry sub = r obtained in the dewatering step, punching and return of the water thus obtained to the quench tank. is characterized by the fact that the UI »stream down high solids content from the separation step has a solids content in the range 10-50% and that the stream down low solids content has a content in the range 3-l0 \. 450 ss; 3. A method according to claim 1, characterized in that the washing of the gas stream takes place in a closed vessel. wherein the gas is introduced from the bottom and flows out from above and that the quench slurry is injected into the gas stream near the bottom of the vessel and the absorber slurry is injected into the gas stream near the top of the vessel, each sprayed slurry being collected separately.