RU2322403C2 - System to prepare make-up water to be added to heat supply system - Google Patents

Abstract

FIELD: heat-and-power engineering, particularly to obtain partly desalted decarbonated make-up water to be introduced into heat supply system.

SUBSTANCE: system comprises serially connected coarse water purification plant provided with clarified water line, reverse-osmosis desalting plant having permeate line and concentrate line and metering unit for metered antiscalant mixing with water. System additionally has bypass clarified water line, which bypasses reverse-osmosis desalting plant and is linked to permeate line, and decarbonization unit included in permeate line and having decarbonated permeate line. Concentration line of reverse-osmosis desalting plant has electrodialysis device with bipolar diaphragms with acid solution conveyance to permeate line upstream of decarbonization unit, with alkaline solution discharge line, which conveys alkaline solution to permeate line downstream of decarbonization unit and with diluate discharge line.

EFFECT: provision of necessary amount of make-up water without the use of marketable reagents, decreased waste mineralized substance discharge into environment, increased degree of inner system mineral sources usage for production of acid and alkali solutions used for make-up water treatment.

3 cl, 1 dwg, 2 tbl, 2 ex

Description

The invention relates to the field of power engineering and can be used to produce partially desalted decarbonized additional water supplied to a heat supply system (STS).

Currently, at thermal power plants (TPPs), district thermal stations (RTS), industrial and heating boiler houses, for the preparation of additional water in STS, water treatment systems are used, including pre-treatment plants (UPR), Na-cationization and / or acidification or Н-Na cations [1] - analogue. The disadvantage of these systems is the significant consumption of commercial reagents (lime, coagulant, NaCl, H ₂ SO ₄ ) and, accordingly, large discharges of sludge water from clarifiers, spent salt and acid solutions, respectively, from Na- and H-cation exchange filters. In the conditions of modern industrial cities, there are strict restrictions on the discharge into the sewer of mineralized effluents. Supplementation of the indicated water treatment systems with plants for processing solid and liquid waste requires very high costs, which is unrealistic, especially with large additions of water to the heating system. Another drawback of the systems [1] is the discharge of spent solutions from Na and H filters containing high concentrations of reactive NaCl and H ₂ SO ₄ .

A known system for the preparation of additional boiler water and waste water treatment at TPPs with a "zero" discharge, including a mechanical filter, a reverse osmosis water desalination plant (six-stage) (UOO I), a deaerator, a chemical desalination plant (HOU), an electrodialysis unit (EDU) for concentrate desalination DOE 1, reverse osmosis desalination unit of the EDU dilution (DOE II). The brine UO, concentrate HOU and purge water of the boilers after the mechanical filter enter the EDU. The brine from the EDU and the concentrate from UOO II are evaporated in the evaporator-crystallizer to separate the salts in solid form [2] - an analog. The disadvantage of this system is the bulkiness of the equipment and the complexity of its operation, as well as the formation of a significant amount of wastewater with a high content of mineral salts. Disposal of the latter to ensure "zero" discharge requires multi-stage concentration with additional evaporation in the evaporator-crystallizer. Another disadvantage of this system is the lack of disposal of valuable reagents contained in the waste.

A known system for the preparation of additional water for STS, containing sequentially connected UPR with a line of clarified water, UOO with lines of permeate and concentrate and a metering unit in the clarified water antiscalant [3] is a prototype.

The disadvantages of the prototype include:

- the absence of a decarbonization unit after DOE, in connection with which the permeate containing CO ₂ is corrosive;

- one hundred percent reverse osmosis desalination of the total water flow into the heating system (TS), which is not required by the quality standards of additional water in the TS and therefore leads to unjustified excessive capital and operating costs;

- low pH values of demineralized water (permeate) UOO (<7) do not meet the requirements for the quality of the additive and network water TS (8.5-9.2 and higher), and therefore, alkalization of the permeate of salable NaOH is required;

- increased constant productivity of UOO, regardless of the set temperature of water heating and other operating conditions of the vehicle;

- discharge of significant costs of concentrate UO, representing a weakly mineralized solution.

Achievable results of the invention are:

- obtaining the required quality of the vehicle’s additional water in accordance with regulatory requirements with virtually no use of commercial reagents and with a limited discharge of mineralized effluents into the environment;

- increase economic, technological and environmental indicators while reducing capital and operating costs;

- maximum use of the internal mineral resources of the system (concentrate UOO) to obtain acidic and alkaline solutions used in the process of processing additional water of the TS.

These results are ensured by the fact that the system for the preparation of additional water for STS, containing sequentially connected UPR with a line of clarified water, DO with lines of permeate and concentrate and a metering unit in the clarified water of antiscalant, according to the invention additionally contains a bypass line with respect to DO of the clarified water connected to the permeate line, the decarbonization unit on the permeate line with the decarbonized permeate line, EDU with bipolar membranes on the UOO concentrate line with the acid solution withdrawal line a line to the permeate line to the decarbonization unit, an alkaline solution withdrawal line to the permeate line after the decarbonization unit, and a dilute discharge line.

In this case, the acid solution drainage line from the EDI can be connected to the clarified water line to the DOE, the alkaline solution drainage line to the source water line to the UPR, and the dilution drainage line to the clarified water line to the DOE.

Additionally, the system according to the invention may comprise a dosing unit in a line of a decarbonized permeate scale inhibitor in STS.

The presence of a bypass line with adjustable valves allows depending on the temperature of water heating in the vehicle to quickly change the flow ratio of demineralized and clarified water, thereby obtaining the quality of additional water that is required for specific conditions of the vehicle (heating temperature, type of heating equipment) while minimizing the consumption of demineralized water.

The reverse osmosis desalination according to the invention is combined with economical methods of water treatment (dosing of an inhibitor and / or an acid solution obtained from an OOE concentrate). Dosing an acidic solution reduces the carbonate index of clarified water and allows you to change the ratio of the costs of desalted and clarified water in favor of the latter, i.e. demineralize lower water discharge at DOE. This, in turn, reduces the capital and operating costs of DOE.

Dosing of the inhibitor allows one to have higher values of the carbonate index (And _k = Ca × Sh, where Ca is the concentration of calcium, Sh is the total alkalinity of water) in the additional water of the TS at moderate heating temperatures (up to 100 ° C), i.e. again reduce the burden on DOE.

The UOO concentrate is sent for processing to EDU with bipolar membranes, as a result of which acid and alkaline solutions are obtained, which are used for corrective treatment of additional TS water. This eliminates the use of commercial acid and alkali in the system, as well as reduces the discharge of UO concentrate. In fact, part of the waste salts of the UO concentrate are processed into acid and alkali.

Alkaline solutions of EDU are used for dosing in permeate, which allows to increase the pH of network water to standard values. The EDU diluate is a UO concentrate partially desalted due to the conversion of salts into acid and alkali. For some low-salinity waters, the diluent can be partially disposed of by mixing it with clarified water. This ensures a low-waste system.

The inclusion of a decarbonization unit on the permeate line ensures the removal of carbon dioxide formed both in the process of reverse osmosis desalination and in the acidification of clarified water. This allows you to effectively alkalize decarbonized water (a mixture of permeate and clarified water), eliminating the unproductive expenditures of alkali obtained in the EDU for the binding of CO ₂ and the conversion of the resulting HCO ₃ ions to CO ₃ .

Dosing an acidic solution into clarified water before DOE is advisable in some cases, for example, when liming the source water in the UPO, after which it is necessary to reduce the pH of the water supplied to the DOE to pH <10. In the same case (when liming the source water in the UPR), it is advisable to dose the alkaline solution obtained in the EDU (the remaining part after dosing in permeate) into the source water before the UPR. Dosing of acid into clarified water to DOE is also advisable at low carbonate hardness, since allows you to refuse dosing antiscalant.

In the drawing, as one example of implementation, a water treatment system for STS according to the invention is shown.

The additional water preparation system for STS contains sequentially connected UPR 1 (for example, clarification filters) with a source water supply line 2 and a clarified water line 3, UOO 4 with permeate and concentrate lines 5 and 6, respectively, and a unit 7 (A) with a metering line 8 into clarified antiscalant water. Additionally, the system according to the invention comprises a clarified water bypass line 9 with a regulating valve 10 connected to the UOO 4 and connected to the permeate line 5 (11 indicates a portion of line 5 after mixing the permeate with clarified water); node 12 (D) of decarbonization on line 5 of permeate with line 13 of decarbonized permeate, EDU 14 with bipolar membranes on line 6 of concentrate UOO 4. Tanks 15 (K), 16 (SH) and 17 (DT) of acid collection, respectively, are connected to EDU 14 , alkaline solutions and diluate with an acid solution withdrawal line 18 from the K 15 tank to the permeate line 5 to the decarbonization unit D 12, an alkaline solution withdrawal line 19 from the Щ 16 tank to the decarbonized permeate line 13. In this case, it is possible to connect the tank To line 15 line 20 (dashed) of the acid solution from the EDU 14 to the clarified water line 3 to UOO 4, to connect the tank Ш16 with the line 21 (dashed) to drain the alkaline solution to the line 2 of the source water and to connect the tank DT 17 with line 22 (dashed) of the diluent drainage to clarified water line 3 to DOE 4. The system may also additionally contain a metering unit 23 (I) along line 24 to line 13 of the decarbonized permeate scale inhibitor in the STS (shown in dashed lines).

The system according to the invention operates as follows. The source water is preliminarily supplied through line 2 to the UPR 1. Part of the clarified water is processed by the antiscalant supplied through line 8 and supplied to the UO 4. Another part of the clarified water is fed through the bypass line 9 with a control valve 10 and mixed with permeate. An acidic solution is supplied to line 11 of the mixture of permeate and clarified water through line 18. The acidified mixture enters the D12 decarbonizer. Line 13 of the decarbonized water is supplied through line 19 with an alkaline solution and, if necessary (in summer mode), through a line 24, scale inhibitor.

Example 1. Tap water after processing on mechanical filters UPR 1 is divided into two streams. One stream of clarified water (60%) entering line 3 is treated with an antiscalant coming in through line 8 and fed to UO 4. Another stream of clarified water (40%) is supplied through bypass line 9 and mixed with permeate supplied through line 5. Mixed the clarified water and permeate flow coming in through line 11 is treated with an acid solution supplied through line 18 and fed to decarbonizer D 12. Decarbonized water is treated with an alkaline solution supplied through line 19, and fed through line 13 to STS (not shown in the drawing ) Table 1 shows the compositions of clarified water, permeate, a mixed stream of clarified water and permeate, a mixed stream after acidification and decarbonization and decarbonized water after alkalization, supplied to the STS. The concentrate UOO 4 in the amount of 20% of the flow of clarified water entering the DOE is fed through line 6 to EDU 14 for partial processing. As a result, after the EDU 14, the resulting acid solution is collected in the tank K 15, the alkaline solution in the tank Щ 16, and the diluent in the tank DT 17. The acid solution from the tank K 15 through line 18 is fed to acidify the mixture of permeate and clarified water. The obtained alkaline solution from the tank Щ 16 through line 19 is fed to alkalization of the decarbonized permeate after decarbonizer D 12. The dilute from the tank DT 17 is discharged. The quality of the water obtained in terms of I _k and pH satisfies the regulatory requirements for heating network water in boilers in the temperature range 121-140 ° С.

Table 1 Composition indicators Clarified water Permeate OOU A mixture of clarified water and permeate Mixed flow after acidification Decarbonated Water After Alkalization Mg-eq / L: Rigidity 3.9 0.06 1,6 1,6 1.76 Calcium 2.7 0.05 1,11 1,11 1.22 Magnesium 1,2 0.02 0.49 0.49 0.55 Alkalinity: NSO ₃ 3.0 0.12 1.27 0.47 0.1 CO ₃ 0,0 0,0 0,0 0,0 0.7 Mg / L: Sodium 96 1,5 39.3 39.3 43.7 Sulphates 120 1,5 48.9 68.1 68.1 Chlorides 89 1,2 36.3 50.6 50.6 Silicates 84 0.15 3.45 3,5 3,5 Saline. 580 13 246 230 240 MgO / L: Oxidizability 3.2 0.5 1,6 1,6 1,6 pH 7.4 5.8 6.9 6.2 8.82 (Mg-equiv / L) ² : And _to 8.1 0.006 1.41 0.52 0.96

Example 2. Groundwater after processing on mechanical filters UPR 1 is divided into two streams. One stream of clarified water (40%) entering line 3 is treated with an antiscalant coming in through line 8 and fed to DOU 4. Another stream of clarified water (60%) is supplied through bypass line 9 and mixed with permeate supplied through line 5. Mixed the clarified water and permeate flow coming in through line 11 is treated with an acid solution supplied through line 18 and fed to decarbonizer D 12. Decarbonized water is treated with an alkaline solution supplied through line 19 and an IOMS inhibitor supplied through line 24 from calculation 4 mg / l and then served in STS (not shown in the drawing). Table 2 shows the compositions of clarified water, permeate, a mixed stream of clarified water and permeate, a mixed stream after acidification and decarbonization and decarbonized water after alkalization, supplied to the STS. UOO 4 concentrate in the amount of 20% of the clarified water flow entering the UE is supplied through line 6 to EDU 14 for partial processing. As a result, after the EDF, the resulting acid solution is collected in the tank K 15, the alkaline solution in the tank Щ 16, and the diluent in the tank DT 17. The acid solution from the tank K 15 through line 18 is fed to acidify the mixture of permeate and clarified water. The obtained alkaline solution from the tank Щ 16 through line 19 is fed to alkalization of the decarbonized permeate after decarbonizer D 12. The dilute from the tank DT 17 is discharged. The quality of the water obtained in terms of I _k and pH with an IOMS content of 4 mg / l meets the regulatory requirements for heating water in network heaters to 100 ° C.

table 2 Composition indicators Clarified water Permeate OOU A mixture of clarified water and permeate Mixed flow after acidification Decarbonized water after alkalization and treatment of IOMS Mg-eq / L: Rigidity 9.5 0.14 5.76 5.76 6.04 Calcium 6.5 0.1 3.94 3.94 4.15 Magnesium 3.0 0.04 1.82 1.82 1.89 Alkalinity: NSO ₃ 6.0 0.23 3,7 2.0 1,6 CO ₃ 0,0 0,0 0,0 0,0 0.8 Mg / L: Sodium 96 1,5 60 60 62.8 Sulphates 240 3.0 145 198 198 Chlorides 89 1,2 54 75 75 Silicates 84 0.15 5.1 5.2 5.2 Solesoder. 970 22 590 562 593 IOMS - - - - four MgO / L: Oxidizability 3.2 0.5 2.1 2.2 2.2 pH 7.6 5.9 7.2 6.8 8.3 (Mg-equiv / L) ² : And _to 39 0,023 14.6 8 9.96

Information sources

1. Protection against internal corrosion of pipelines of water heating networks. / Balaban-Irmenin Yu.V., Lipovsky V.M., Rubashov A.M. // M .: Energoatomizdat, 1999, pp. 34-37.

2. Improving the environmental safety of thermal power plants. / Abramov A.I., Elizarov E.P., Remizov A.N. and etc.; Ed. A.S. Sedlova. - M.: Publishing House MPEI, 2001, p. 344, 343.

3. Operating experience of reverse osmosis water desalination plants at thermal power plants and in industrial boiler houses. / Askernia A.A., Malakhov I.A. Korabelnikov V.M. et al. // "Thermal Power Engineering", No. 7, 2005, p. 21.

Claims (3)

1. A system for preparing additional water for heat supply systems, comprising a water pretreatment unit with a clarified water line, a reverse osmosis desalination unit with permeate and concentrate lines, and an antiscalant dosing unit for clarified water, characterized in that it further comprises a bypass with respect to the installation reverse osmosis desalination the clarified water line connected to the permeate line, the decarbonization unit on the permeate line with the decarbonization line vannogo permeate electrodialysis with bipolar membranes installation for installing a concentrate line with a reverse osmosis desalination discharge line acid solution in the permeate line to the node decarbonation discharge line to an alkali solution after the assembly line the permeate discharge line and decarbonization diluate. 2. The system according to claim 1, characterized in that the drainage line of the acid solution from the electrodialysis unit is connected to the clarified water line before the reverse osmosis desalination plant, the drainage line of the alkaline solution is connected to the source water line before the pre-treatment of water, and the dilution drainage line is connected to lines of clarified water before installing reverse osmosis desalination. 3. The system according to claim 1, characterized in that it further comprises a dosing unit in the line of decarbonized permeate scaling inhibitor in heat supply systems.