RU2056152C1 - Apparatus for preparation of reactants solutions and measuring them out in doses - Google Patents

Abstract

FIELD: water supply, chemical food processing industries. SUBSTANCE: apparatus for preparation of solutions and measuring them out in doses has solutions preparation tank with fire-grate for location of firm phase of reactant, small tank for measuring initial water out in doses, The small tank is located above level of solutions preparation tank and has siphon drain linked to solutions preparation tank. Overflow pipeline connects solutions preparation tank with intermediate capacity. Apparatus has water spraying pump, intake branch pipe of which is located in intermediate capacity and delivering branch pipe is connected with lower part of delivery controlling reservoir, upper part of which is connected through compressed air pipeline with airlifting pipe of solutions preparation tank. Delivery controlling reservoir has discharging pipeline and solutions preparation tank has washing pipeline. EFFECT: improved design. 2 cl, 3 dwg

Description

 The invention relates to the field of water treatment and can be used in the reagent farm of natural and waste water treatment plants, as well as in the chemical and food industries.

A device for preparing a coagulant solution containing a wet storage tank, a chemical pump for pumping the prepared solution and a perforated pipe for supplying compressed air or steam [1]
The disadvantages of the device are as follows.

1. The wet storage tanks of the coagulant, which are also solution tanks, have a large volume, since, in addition to placing the coagulant, they must contain the volume of water necessary for its dissolution. Given the fact that the concentration of the saturated coagulant solution in the pure substance is 17-24%, the specific volume of solution tanks per ton of commercial product is 2.2-2.5 m ³ . This factor leads to an increase in capital costs and the size of the occupied area.

 2. The intensification of the dissolution of the reagent is carried out by bubbling with compressed air or steam, which is associated with high energy consumption.

 3. the need to use chemically resistant pumps, which leads to an increase in capital costs.

 A device [2] containing a pressure tank with a drainage grate, pipelines for supplying source water, compressed air and draining the reagent solution is known. Its disadvantages include the shortcomings in paragraphs 1 and 2 of the considered device, as well as the need for complete tightness of the tank, which significantly limits the use of this device at water treatment plants due to the complexity of the reagent loading process.

 Closest to the invention is the technical solution given in [3]. It contains an open solution tank with a perforated baffle, a tank for maintaining a constant level in the solution tank, a measuring device (dispenser) of a saturated solution, a steam supply pipe for heating the solution, and a water-jet a pump designed to pump sludge from a solution tank.

 The device operates as follows.

 The reagent is loaded into the solution tank and filled with water. If the tank is located outdoors at a negative outside temperature, steam is supplied to it for heating. After saturation of the solution, it is passed in portions to the measuring device, while the source water enters the solution tank through the reservoir of maintaining a constant level. A saturated solution from the measuring device is fed by gravity to the place of mixing or entering into the treated water, and the water entering the tank is saturated with the reagent, and the saturation process occurs under static conditions. This mode of preparation and dosing of the solution is continued until there is a sufficient volume of the solid phase of the reagent in the solution tank, which ensures saturation of the source water during the time during which the volume of the solution coming from the measuring device is used. The sludge from the mortar tank is removed using a water-jet pump, the suction pipe of which is placed in the pit.

 The disadvantages of the prototype include the following.

 1. Low intensity of reagent dissolution due to the lack of constant movement of the solution relative to the solid phase of the reagent, which leads to an increase in saturation time, an increase in the volume of the measuring unit and an increase in capital costs.

 2. The operations of transferring the saturated solution to and from the measuring unit are carried out by switching the locking elements, which necessitates the participation of service personnel and leads to an increase in operating costs.

 3. The supply of the prepared solution can be carried out at a point located no higher than the level in the solution tank, which limits the scope of this device.

 The technical result of the invention is the reduction of capital and operating costs, as well as the automation of the dosing process of the reagent solution.

 The indicated effect is achieved by additional equipment of the device with an airlift pipe connecting the lower and upper parts of the solution tank, a pressure-regulating tank, the suction pipe of the water-jet pump is placed in an intermediate tank, and the discharge pipe is connected to a pressure-regulating tank, the upper part of which is connected with the lower part of the air-lift pipeline, the source water metering tank is equipped with a siphon, and the mortar tank is connected to the intermediate tank by an overflow pipe. In this case, a circulation loop is formed, which includes a mortar tank and an airlift pipe, the working medium of which is compressed air, which enters the lower part of the airlift pipe from a pressure-regulating tank. Due to the circulation that ensures the movement of the solution relative to the solid phase of the reagent, the dissolution process is intensified and the time of saturation of the source water is reduced, which leads to a reduction in the required volume of the measuring unit, since portions of the prepared saturated solution can be discharged more often. The presence of a tank for dosing the source water, equipped with a siphon, provides automatic dosing of the saturated reagent solution with a constant volume and time interval, since when a portion of the source water enters the solution tank, the equal volume of the portion of the saturated solution flows through the overflow pipe into the intermediate tank, from where it is supplied water-jet pump into the pressure-regulating tank and further to the place of entry. In this case, the concentrated reagent solution is diluted to the optimal concentration, which, according to [1, p. 87], provides a pH of 4.5–4.7 when, for example, hydrolysis of, for example, aluminum sulfate, instead of its hydroxide, basic sulfates are formed, which have a higher sorption ability, which allows to reduce reagent consumption. On the other hand, batch (intermittent) dosing, which according to [4] also makes it possible to reduce the dose of the reagent, is carried out without the direct participation of maintenance personnel.

 Thus, these features of the invention can reduce operating costs compared with the prototype. The presence of the indicated relationship of the water-jet pump with an intermediate tank and a pressure-regulating tank, and the latter with an airlift pipe, makes it possible with one device (water-jet pump) to pre-mix the reagent with water, transport the diluted solution to the injection site and constantly stir the solution in the solution tank. This is achieved due to the fact that the performance of the water-jet pump is greater than the flow rate entering the source water metering tank. At the same time, there are time intervals when the intermediate tank is empty and the water-jet pump draws in atmospheric air and delivers the air-water mixture to the pressure-regulating tank, from where water is discharged into the processed stream, and compressed air to the lower part of the airlift pipe. When a reagent solution is pumped out by a water-jet pump, the flow rate of the mixture after it exceeds the flow rate discharged from the pressure-regulating tank. A liquid with a flow rate equal to the difference of the indicated flows enters the pressure-regulating tank, displacing air into the airlift pipe of the solution tank. This ensures continuous circulation in the solution tank.

 In order to further improve the invention, the full use of the reagent and simplify its operation, it is equipped with a similar mortar tank. The tanks are interconnected by a bypass pipe. The technical effect is achieved as follows. With a decrease in the volume of the solid phase of the reagent in the first solution tank, when the source water is not saturated during the filling of the metering tank, the overflow pipe of the first solution tank is closed, and the bypass pipe is opened into the second solution tank. The depleted solution flows from the first solution tank to the second, where it is saturated, and at the same time the first solution tank is washed until the solid phase of the reagent is completely dissolved and the solution concentration in it drops to zero. After this, only the second mortar tank works.

 On fi. 1, 2 show embodiments of the device according to the invention; figure 3 the nature of the change in mass flow rate of the reagent at the outlet of the installation.

 A device for preparing a reagent solution (Fig. 1) contains a solution tank 1 with a grate 2 and a solid phase of reagent 3 placed in it, a tank 4 for dispensing the source water, located above the level in the solution tank and equipped with a siphon made according to the principle known (siphon biofilter metering tank), with the lower end of the siphon placed relative to the level in the solution tank with a jet break. The overflow pipe 5 is in communication with an open intermediate tank 6 located below the level in the solution tank, and the volume of the intermediate tank is not less than the volume of the tank for dispensing the source water. The suction nozzle of the water-jet pump 7 is in communication with the intermediate tank, and the discharge is connected to the lower part of the pressure-regulating tank 8, the upper part of which is connected by a compressed air pipe 9 to the lower part of the airlift pipe 10 of the mud tank. The pressure-regulating tank is equipped with a discharge pipe 11 in communication with the injection site of the reagent, and a solution tank with a wash pipe 12.

 The device operates as follows.

The source water is supplied to the discharge pipe of the water-jet pump 7 and the tank 4 for dispensing the source water, and the flow entering the latter is less than the capacity of the water-jet pump. During time t ₁ , when the intermediate tank 6 is completely empty, the water-jet pump 7 draws air from the atmosphere and delivers the air-water mixture to the pressure-regulating tank 8, from where water is discharged through the pipe 11 to the processed stream, and compressed air through the pipe 9 to the lower part airlift pipe 10, providing circulation in the circuit, including the mortar tank and airlift pipe. In this case, the water flow discharged from the pressure-regulating tank exceeds the water flow supplied by the water-jet pump, which is achieved by appropriate throttling on pipelines 9 and 11. The water level in the tank 8 gradually decreases and when the intermediate tank is filled with another portion of the saturated solution, it becomes minimal (WELL). When pumping out the reagent solution from the intermediate tank, the water-jet pump 7 delivers a mixture flow rate over time t ₂ that exceeds the flow rate discharged from the pressure-regulating tank 8, as a result of which the level in it rises and the displaced air enters the airlift pipe 10, providing continuous circulation in a solution tank. Moreover, the filling time of the tank 4 for dispensing the source water is t ₁ + t ₂ and is the cycle time of the installation. The nature of the change in the mass flow rate of the reagent at the outlet of the installation is shown in Fig. 3, where t _{3 is the} time during which the reagent solution is diluted in the pressure-regulating tank after it is stopped by the water-jet pump from the intermediate tank.

 The device according to paragraph 2 is shown in figure 2, it additionally contains a similar mortar tank, a bypass pipe 13 and shutoff valves 14-20.

 A feature of the operation of the device according to paragraph 2 is that when the concentration of the solution in the solution tank 1 decreases, which is a consequence of a decrease in the volume of the solid phase of the reagent, the lean solution is transferred from tank I to tank II, where it is saturated. In this case, the locking device 15, 14, 18, 20 are open, the rest are closed. After complete dissolution of the solid phase of the reagent in the tank 1 and the concentration of the solution in it to zero, close the shut-off devices 14, 15 and open 16. Similarly, switch from the second solution tank to the first.

 Examples of specific performance.

1. The described installation was investigated on a laboratory bench with the following structural and technological parameters: height of the mortar tank 1000 mm diameter of the mortar tank 105 mm diameter of the airlift pipe 20 mm
volume of a tank for dosing of initial water of 0.8 l
pressure regulating tank height 400 mm
diameter of pressure regulating tank 105 mm
working pressure of a water-jet pump 0.2 MPa
feed water flow through a water jet pump 360 l / h
performance in
of a submersible pump for a solution of 50 l / h by air 345 l / h
feed water consumption
entering the metering tank 19.2 l / h
The installation was carried out on tap water without the use of a reagent. At the same time, the filling time of the tank for dosing the source water (cycle time) T 2.5 min, the time of pumping the solution from the intermediate tank t ₂ 1 min, the time of suction of the atmospheric air with a water-jet pump t ₁ 1.5 min. The indicated parameters were automatically maintained for 30 cycles. The flow rate in the circulation circuit of the airlift pipe solution tank was 155 l / h at t ₁ and 120 l / h at t ₂ . The flow rate at the outlet of the installation varied from 360 l / h at t ₁ to 330 l / h at t ₂ . This is due to a change in pressure loss at the suction of the water-jet pump during suction of the solution or air. As a result, the pressure in the pressure-regulating tank also varied from 0.02 MPa at t ₁ to 0.017 MPa at t ₂ .

 Compared with the prototype, the device according to the invention has the following advantages.

 1. Intensifies the process of dissolution of the reagent due to the organization of circulation in the circuit, which includes a solution tank. As a result, the volume of the container for accommodating the prepared solution is reduced. It should also be noted that circulation is provided along the way with the main function of the water-jet pump, which consists in diverting the reagent into the treated stream. In addition, the water-jet pump performs the function of a pre-mixer, which in some cases (for example, in the case of dosing aluminum sulfate, as discussed above) can reduce the reagent consumption.

2. The installation provides automatically intermittent dosing of the reagent, and the magnitude of the administered dose, as well as the intervals of administration can be changed "on the fly". In addition, this setting can be considered as a setting that provides a constant dose, if the value of the interval t ₁ set the minimum.

 3. In contrast to the prototype, the proposed technical solution provides the supply of a reagent solution to anywhere in the technological scheme of water treatment, since the solution is supplied under pressure. This extends the scope of the installation without the use of chemically resistant pumps.

Claims (2)

 1. DEVICE FOR PREPARING AND DOSING THE REAGENT SOLUTION, comprising a solution tank with a grate, a metering tank for initial water and an intermediate tank associated with it, a water-jet pump and a discharge pipe, characterized in that the device is equipped with a pressure-regulating tank, a suction nozzle of the water-jet pump placed in an intermediate tank, and the discharge connected to the pressure-regulating tank, the device is equipped with airlift pipe connecting the upper part of the pressure-regulating the reservoir with the upper and lower parts of the mortar tank, the metering tank of the source water is equipped with a siphon, and the mortar tank is connected to the intermediate tank using an overflow pipe.  2. The device according to p. 1, characterized in that it is equipped with an additional solution tank, similar to the existing one, and a bypass pipe connected to it.

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