RU2129993C1 - Method and installation for neutralizing sewage - Google Patents

Abstract

FIELD: waste water treatment. SUBSTANCE: invention can be used for continuously treating alkaline and acidic drains from water-treating plants and steam generating units of heat-and-power stations. Method includes filling accumulation tanks with mentioned drains followed by simultaneously feeding drains into reactor mixer from tanks and adjusting consumption of one of the drains being neutralized. Once accumulation tanks filled, drains are stirred and maximum allowable uptake of drains is determined bearing in mind necessity for their complete neutralization. Further, drains from accumulation tanks are simultaneously fed into reactor mixer and therefrom into discharge line until one of the accumulation tanks is emptied. Feeding drains is then interrupted, one or two accumulation tanks are replenished, and drains are restirred cyclically and subsequent operations repeated. Invention is distinguished by that drains in reactor mixer are subjected to cavitation hydromechanical treatment. Installation contains two accumulation tanks, feeding pump, control panel, pH measuring instruments, drain-intake regulators on inlets and outlets of accumulation tanks, three mixture-consumption regulators, reactor mixer outlet provided with mixture-consumption regulator connected with accumulation tank inlets and discharge line. EFFECT: increased productivity of process. 10 cl, 1 dwg, 3 ex

Description

 The invention relates to a device for neutralizing industrial effluents and can be used for continuous treatment of alkaline and acidic effluents from water treatment plants and boiler plants of thermal power plants.

 A known method of neutralizing alkaline and acidic effluents, including the simultaneous filling of alkaline and acidic effluent of the neutralization tank (reactor), measuring the pH of the medium in the neutralizing tank and adding, if necessary, a reagent for final neutralization. To implement the method, a device is used that contains a neutralizing tank, drains and neutralizing agent supply lines, as well as a control system that measures the pH of the medium in the neutralizing tank and adjusts the supply of reagent (see a. P. 1502482, C 02 F 1 / 66, 1989; A.S. 789418, С 02 F 1/66, 1979; ac 1006386, С 02 F 1/66, 1983; A.S. 1201232, С 02 F 1/66, 1985; 922085, С 02 F 1/66, 1982). These method and device for its implementation have low productivity, because the process of neutralizing the environment takes a lot of time. In addition, in the known method and device during adjustment, fluctuations in the pH of the medium of significant amplitude occur due to the inertia of the pH measurement process. This reduces the efficiency of neutralization, negatively affects performance. And finally, the disadvantages of the known solutions include the high rate of formation and deposition of sediments in the neutralization tank and highways.

 In the application of Germany N 2910679, C 02 F 1/66, 1980, a method and device for neutralizing wastewater are described, in which two storage reactors and a recirculation line are used, as well as measuring devices for acid and alkali.

 The effectiveness of the data of the method and device is higher than considered, because the use of the circulation circuit allows to reduce the time of neutralization of effluents. Nevertheless, the indicated time is still quite large and, depending on the pH and flow rates of each of the neutralized flows, can reach several hours. In addition, the precipitate formed in the reactors, consisting of insoluble and poorly soluble salts (usually calcium, magnesium and iron), can lead to clogging of the circulation circuit and the discharge line of neutralized effluents, the need to stop and clean the equipment, which reduces the reliability of the installation as a whole.

 Closest to the proposed are the method and device for neutralizing wastewater described in a. with. N 789419, C 02 F 1/66, 1979. The known method includes filling the storage tanks with acid and alkaline effluents, respectively, subsequent simultaneous supply of effluents from the tanks to the reactor-mixer, continuously measuring the pH of the medium in the reactor-mixer and adjusting the flow rate of one of the neutralized effluents. The device includes two storage tanks connected through pumps and supply lines to the inputs of the reactor-mixer, the output of which is the output of the device. A pH meter is placed in the reactor-mixer, the output of which is connected to the input of the control unit, the output of which is connected to the control input of one of the supply pumps.

 However, in the known solution, the productivity is limited by the time of the extensive reaction in the mixer, as well as by a significant control time constant. In addition, the neutralization efficiency is low due to delays in the control circuit, which leads to significant fluctuations in the pH of the output. And finally, the disadvantages of the known solutions include the rapid overgrowth of the reactor-mixer and the output line with insoluble and sparingly soluble deposits.

 Thus, the technical result expected from the use of the invention is to increase the productivity of the method and device for its implementation, eliminating the discharge of acidic or alkaline effluents, increasing the life of the equipment for neutralization.

 This result is achieved by the fact that in the known method of neutralizing wastewater, including filling the storage tanks with acid and alkaline wastewater, respectively, the subsequent simultaneous supply of wastewater from the tanks to the reactor-mixer and adjusting the flow rate of one of the neutralizable wastes, after filling the storage tanks with acid and alkaline wastewater, effluents, measuring the pH of the medium in storage tanks and determining the optimal flow rate from conditions of complete neutralization and maximum the course of the wastewater, then the optimal flow rate of both wastewater is recorded and the wastewater is simultaneously supplied from the storage tanks to the reactor-mixer, and from it to the outlet line until one of the storage tanks is emptied, after which the sewage supply is interrupted, supplement one or both of the storage tanks and cyclically repeat the mixing of wastewater in augmented storage tanks, measuring the pH of the medium in them, determining the optimal flow rate and the simultaneous supply of effluents with the optimal flow rate from the storage tanks a reactor-mixer to discharge one of the storage tanks.

 It is also recommended to use mechanical and / or circulating mixing of effluents.

 In this case, the circulating mixing of the effluent can be carried out by passing the effluent through a reactor-mixer.

 Moreover, the addition of storage tanks can be made by the same and / or opposite drains and / or reagents.

 It is also advisable to supplement the storage tanks with reagents in the process of mixing effluents.

 In addition, in the process of supplying effluents from storage tanks to the reactor-mixer, reagents can also be fed there.

 In addition, in the reactor-mixer, the effluent can be subjected to cavitation hydromechanical treatment.

 The specified result is also achieved by the fact that the known device for neutralizing wastewater containing two storage tanks, a feed pump, the output of which is connected to the input of the reactor-mixer, a pH meter, the output of which is connected to the first input of the control unit and the output line, is equipped with four flow controllers effluent, a second pH meter and three mixture flow regulators, while the first pair of effluent flow regulators is installed at the inputs of storage tanks, at the outputs of which a second a second pair of flow controllers, the outputs of which are combined and connected to the input of the feed pump, the output of the reactor-mixer through the corresponding flow controllers of the mixture is connected to the inputs of the storage tanks and the output line, with pH meters installed in the storage tanks, the output of the second pH meter connected to the second input of the control unit, the outputs of which are connected to the control inputs of the flow controllers.

 In addition, storage tanks can be made with level sensors, the outputs of which are connected to the third and fourth inputs of the control unit.

 It is also advisable to equip the device with one or two reagent containers made with pH meters and level sensors, the outputs of which are connected to the fifth, sixth, seventh and eighth inputs of the control unit, as well as reagent flow regulators installed on the inputs of the reagent containers and between the outputs tanks for reagents and the input of the feed pump, respectively, and the control inputs of the flow rate controllers of the reagent are connected to the corresponding outputs of the control unit.

 And finally, tanks can be made with input cross-flow controllers, the outputs of which are connected to the inputs of opposite storage tanks.

 In FIG. 1 shows a block diagram of a device for implementing the method. The device contains storage tanks 1.2 and 3.4 tanks for reagents. Flow controllers 5–8 are installed at the inputs of capacities 1–4, respectively, and flow controllers 9–12 are installed at their outputs, while controllers 5, 9, 8, and 12 are flow rate controllers, and 6, 7, 10, and 11 are reagents . The device also contains regulators 13, 14 and 15 of the mixture flow, a feed pump 16, the output of which is connected to the input of the reactor-mixer 17, the output of which is connected to the combined inputs of the regulators 13-15. In the capacities 1-4 are the primary converters of the meters 18-21 pH of the medium, the outputs of which are connected to the inputs of the control unit 22. All connections of the elements through which drains or reagents pass in the device are made by the corresponding highways 23. In tanks 1-4, level 24-27 sensors can be installed. The cross-flow controllers 28-31 are connected to the respective input lines 32-35. 36 indicates the output line.

 All lines in figure 1 are indicated by thick lines. Under opposite drains (reagents), containers for them, etc. understand acidic effluents (reagents), tanks for acidic effluents, etc. in relation to alkaline drains, tanks for them, etc. and vice versa. Thus, the connection of flow controllers 28-31 to the inputs of opposite containers means that if tank 1 is filled with acidic drains, tank 2 is alkaline, tank 3 is an acidic reagent, and tank 4 is alkaline, the outputs of the regulators 28 and 29 (see Fig. 1) are connected to capacity 2, and the outputs of the regulators 30 and 31 are connected to capacity 1. If, in this example, the capacity 4 is filled with acidic reagent and capacity 3 is alkaline, then the output of controller 29 will need to be connected to capacity 1, and the output of controller 30 - to capacity 2. It is also conditionally understood and used in describing the concept of input and output elements through which the reactants, or a mixture of waste water: connection to the input means, the reagent mixture or drain enter the corresponding element, connection to the output - that they come out of it.

 As flow regulators, you can use controlled valves, gate valves and other components that allow you to set a fixed flow in the line.

 Sensors 24-27 can be double, fixing both the filling and emptying of the respective containers. The corresponding signals, arriving at block 22, serve to develop a decision to start or stop the process of neutralization, the transition to its next stage. Of course, fixing the filling or emptying of containers can be done visually.

 The reactor-mixer 17 can be made in the form of a tank or a tank with a stirrer. However, the best results are obtained by using a cavitation mixer, the performance of which is described in the overview information "Improving the operational properties of liquid boiler fuel by its hydromechanical processing." - M., 1986.

 Block 22 can be made in the form of a control panel, on which level indicators from sensors 24-27, pH indicators of meters 18-21, control elements of regulators 5-15, 28-31, pump switch 16 are displayed. In this case, the operator controls the operation of the device . In this case, the choice of the optimal flow rate of the effluent can be made according to the nomogram or the reaction equation. The nomogram can be obtained experimentally or by calculation. For example, if the reaction and the pH of the effluent are such that for complete self-neutralization of effluents, i.e., neutralization when they are mixed in the absence of reagents, 0.657 kg of acidic per 1 kg of alkaline effluent is required, and the maximum flow rates in the corresponding lines are equal, it is advisable to establish the flow rate with alkaline runoff maximum (open the valve completely), and set the flow rate of acidic runoff at 0.657 of the maximum.

 Block 22 can also be made in the form of an autonomous microprocessor block that selects the optimal flow rate and controls the operation of the device based on data on the pH of the medium in containers 1-4, information from sensors 24-27 and the algorithm of the device below.

 The device depicted in figure 1, allows you to implement the neutralization method in automatic or semi-automatic mode, with the addition of reagents or without it, with cross-filling containers or without it. First, however, we consider how to implement the method in the simplest case, while simultaneously describing the operation of the device.

 First, by opening regulators 5 and 8, tanks 1, 2 are filled with acidic and alkaline drains. Acidic and alkaline drains from the chemical water treatment department (after operation and / or regeneration of cationic and anionic filters), as well as acidic drains from washing the heating surfaces of boilers from The boiler shop separately enters the storage tanks 1 and 2. In this case, all other shut-off pipe fittings are in a closed state. In particular, the regulators 9 and 12 are closed, the pump 16 is turned off, the reactor-mixer 17 does not work. Then the drains are mixed in containers 1, 2. Stirring of the drains can be carried out in any known manner. At the same time, mechanical stirring is understood to mean stirring produced by a stirrer installed in an appropriate vessel, and circulation is understood as stirring by passing the medium through an apparatus mixer (reactor-mixer 17) external to the vessel. In the latter case, after filling the containers 1, 2, the regulators 5, 8 are closed and first the regulators 9 and 13 are opened, turning on the pump 16, and by establishing the constant readings of the meter 18, i.e. after mixing the medium in the tank 1, close the regulators 9, 13 and open the regulators 12, 14 (the regulator 15 is closed all this time). After the readings of meter 21 are also established, i.e. the effluents in both tanks 1, 2 are mixed, determine the effluent costs optimal from the point of view of maximum productivity and complete neutralization, and fix the regulators 9 and 12 in the corresponding position, ensuring the simultaneous supply of both effluents in quantities ensuring complete neutralization, using pump 16 to the reactor inlet -mixer 17. At the same time, the regulators 13, 14 are closed, and the regulator 15 is fully open, so that the neutralized effluents enter the highway 36.

 The neutralization process is interrupted at the moment of emptying one of the containers, say tank 2, for which they close the regulator 15, turn off the pump 16 and close the regulators 9 and 12. If at this moment the tank 1 is, for example, 80% full, it is advisable to fill the tank 2 again with the above Thus, to mix the effluents in it and, having specified the optimal consumption of effluents, continue the process of neutralization. After 4-5 such cycles, you can simultaneously add tanks 1 and 2, mix the drains in them and continue the process. If, after emptying the tank 2, the tank 1 is filled, say, by 10%, it is better to immediately add both tanks, to make alternating or simultaneous mechanical mixing and resume the neutralization of effluents in the optimal ratio of costs.

 From the above description it follows that all regulators, except for regulators 9-12, can be made on-off, in the form of valves with two positions: fully open and completely closed. The disadvantage of one of the effluents can be compensated by adding the appropriate reagent (with an excess of acidic effluent - an alkaline reagent and vice versa). In this case, the corresponding reagent can be introduced directly from the line 33 through the regulator 29 into the tank 2 or through the regulator 6 into the tank 3, and after stirring in it (if necessary) and measuring the pH of the reagent with a meter 19, the reagent can be added in the required amount to the tank 2 in the process of mixing wastewater in it by simultaneously opening and closing the regulators 10, 12 and 14, or introduced directly into the reactor-mixer 17 in the process of neutralization, for which the regulator 10 is set to the position fixing the optimum descent of reagent together with regulators 9, 12 and 15.

 In addition to the described options, the addition of tanks 1, 2 can be carried out by opposite drains (tanks 1 from the highway 35, tanks 2 from the highway 32) through the regulators 28 and 31. This is also a correction of the composition of the reagent to increase the productivity of the device and method by bringing the costs of the drains closer from tanks 1, 2.

 Pre-mixing of each of the effluents in the corresponding storage tank until the pH value is averaged (which happens quite quickly) allows for complete self-neutralization of effluents or neutralization of effluents using a reagent.

 The implementation of the reactor-mixer 17 in the form of a hydrodynamic (hydromechanical) cavitation mixer allows you to get neutral drains with a single passage of the latter.

 The use of a hydrodynamic cavitation mixer in the circulation circuit makes it possible to significantly intensify the process of mixing the mixture components (acid and alkaline effluents, and, if necessary, reagents - acid or alkali), and therefore increase the efficiency of neutralization.

 As the studies showed, this is due to the collapse of the vapor-gas bubbles formed in the liquid stream and the release of a short-term powerful pulse in the form of a spherical shock wave, which contributes to the mixing of the components of the liquid stream and the grinding of solid inclusions. Each oscillating bubble can be considered as a micro-generator of ultrasonic vibrations, the specific characteristics of which are comparable to those of industrial acoustic generators used to intensify technological processes.

Example 1. In storage tanks 1 and 2 with a volume of 20 m ³ each is filled with 16 m ^{3 of} alkaline and acidic effluents. After that, using pump 16 and mixing reactor 17, alkaline effluents are mixed until pH 12 is averaged, and then acidic effluents are similarly mixed until pH 3 is averaged. Using block 22, a flow ratio of 10 m ³ acid effluents per 1 m ³ alkaline is established. In this case, the total runoff has a pH of 7. After emptying the storage tank 2 with acidic drains, 14.4 m ^{3 of} alkaline waste water remains in the storage tank 1. Then the storage tank 2 is again filled with acidic effluents and the process of self-neutralization of effluents is repeated.

Example 2. The method is carried out as in example 1, but after emptying the storage tank 2 with acidic drains, fill up to 16 m ³ with the corresponding drains both storage tanks 1, 2, after which the process of self-neutralization of the drains is repeated.

Example 3. The method is carried out as in example 1, but after emptying the storage tank 2 with acid effluents, 14.4 m ^{3 of} alkaline effluents from the storage tank 1 are brought into interaction with 1.44 m ^{3 of an} acidic reagent (HCl) with pH 1. After that, both storage tanks 1, 2 are again filled with the corresponding drains and the processes of self-neutralization and neutralization of drains are repeated.

 The use of this technical solution allows for almost instantaneous neutralization of effluents, which means to significantly increase equipment productivity, and also eliminates clogging of equipment with insoluble and poorly soluble sludge, which in turn increases the reliability of its operation. In addition, a strictly neutral medium enters the output line, so that the effectiveness of the proposed method and device is significantly higher than that of the known ones.

Claims (10)

 1. A method of neutralizing effluents, including filling the storage tanks with acid and alkaline effluents, respectively, subsequent simultaneous supply of effluents from the containers to the reactor-mixer and adjusting the flow rate of one of the neutralized effluents, characterized in that after filling the storage containers with acid and alkaline effluents, they mix the effluents, measuring the pH of the medium in storage tanks and determining the optimal flow rate from the conditions of complete neutralization and maximum flow rate, then fix the maximum flow rate of both wastewater and the simultaneous supply of wastewater from the storage tanks to the mixer reactor, and from it to the outlet line until one of the storage tanks is emptied, and in the mixer reactor, the drains are subjected to cavitation hydromechanical treatment.  2. The method according to claim 1, characterized in that use mechanical and / or circulation mixing of the effluent.  3. The method according to p. 2, characterized in that the circulating mixing of the effluent is carried out by passing the effluent through a reactor-mixer.  4. The method according to claim 1, characterized in that the addition of storage tanks produce the same and / or opposite drains and / or reagents.  5. The method according to claim 4, characterized in that the addition of storage tanks with reagents is carried out in the process of mixing wastewater.  6. The method according to claim 4, characterized in that in the process of supplying effluents from the storage tanks to the reactor-mixer, reactants are also fed there.  7. A device for neutralizing effluents, containing two storage tanks, a feed pump, the output of which is connected to the input of the reactor-mixer, a pH meter, the output of which is connected to the first input of the control unit and an output line, characterized in that it is equipped with four drains flow control , a second pH meter and three mixture flow regulators, while the first pair of effluent flow regulators is installed at the inputs of storage tanks, the outputs of which have a second pair of flow regulators shackles, the outputs of which are combined and connected to the input of the feed pump, the output of the reactor-mixer through the corresponding flow controllers of the mixture is connected to the inputs of the storage tanks and the output line, and the pH meters are installed in the storage tanks, the output of the second pH meter is connected to the second input of the control unit the outputs of which are connected to the control inputs of the flow controllers.  8. The device according to claim 7, characterized in that the storage tanks are made with level sensors, the outputs of which are connected to the third and fourth inputs of the control unit.  9. The device according to claim 7, characterized in that it is equipped with one or two containers for reagents made with pH meters and level sensors, the outputs of which are connected to the fifth, sixth, seventh and eighth inputs of the control unit, as well as reagent flow regulators installed at the inputs of the tanks for reagents and between the outputs of the tanks for reagents and the input of the feed pump, respectively, and the control inputs of the regulators of the flow of the reagent are connected to the corresponding outputs of the control unit.  10. The device according to claim 7, characterized in that the tanks are made with input cross-flow controllers, the outputs of which are connected to the inputs of the opposite storage tanks.