RU2214370C1 - Plant to saturate water with ozone - Google Patents

Abstract

FIELD: water treatment by oxidation with use of ozonization. SUBSTANCE: invention can be employed for disinfection, clarification and deodorization of drinkable water in water supply systems of towns and other populated areas, for disinfection of circulating water in swimming pools and for purification of sewage of industrial enterprises. Plant includes contact column with pipe unions for inlet/outlet of working/used gas and with branch pipes for inlet/outlet of water into contact column and out of it correspondingly, pump connected to inlet branch pipe of contact column, compressor to which outlet inlet of unit generating ozone-air mixture is linked. Outlet of unit generating ozone is linked to inlet pipe union located in lower part of contact column partially filled with contact elements. Inlet branch pipe is positioned in upper part of contact column, outlet branch pipe is located in lower part of contact column. Relation of flow rate of water V_w and gas V_g should comply with following proportion V_w:V_g = (0,05-0,5):1. EFFECT: increased ecological safety and reliability of plant, reduced energy consumption, cost and dimensions of plant. 5 cl, 1 dwg

Description

 The proposed installation relates to techniques for treating water by oxidation using ozonation. It can be used, in particular, for disinfection, clarification and deodorization of drinking water in the water supply systems of cities and other settlements, for disinfection of circulating water of pools and for wastewater treatment of industrial enterprises.

 A known analogue of the proposed one is an installation that implements a method for producing water with a high concentration of ozone [1] (EP 0430904 A1, C 02 F 1/78, 05.06.91), in which the ozone-containing gas is in contact with the source water sprayed in the form of small drops. The installation comprises a chamber, in the upper part of which nozzles for spraying the source water and nozzles for supplying ozone-containing gas are located, and in the lower part, in which the treated water is accumulated, there is a nozzle for draining it.

 A disadvantage of the known analogue [1] is its increased energy intensity due to the need for fine dispersion of large masses of the processed fluid. In addition, a decrease in the efficiency of ozonation is due to a violation of the principle of counterflow, which is generally recognized as optimal for mass transfer processes.

 It is also known a device for ozonation of water [2] (RU 2114790 C1, C 02 F 1/78, 07/10/1998), containing an air preparation system connected to an ozone generator equipped with a power source, a reaction vessel, in the lower part of which there are dispersants, communicated with the ozone generator, as well as a system for processing excess ozone.

 The disadvantage of the analogue [2] is its increased energy intensity, due, firstly, to the need to produce an increased amount of ozone due to its non-optimal use in water treatment and, secondly, the subsequent energy consumption for the decomposition of excess ozone.

 Closest to the proposed technical solution is a device for wastewater treatment [3] (RU N 2002707 C1, C 02 F 1/78), adopted as a prototype of the proposed and containing a contact column with inlet / outlet fittings for inlet / outlet of working / waste gas and inlet / outlet nozzles for input / output of source / ozonated water into and out of the contact column, as well as a pump connected to the inlet of the contact column, a compressor to the output of which the input of the ozone-air generation unit is connected B, whose output is connected to the inlet located at the bottom of the contact tower, partially filled contact elements, which coincides with the essential features of the proposed installation.

 In the specified prototype, in addition, the inlet pipe is placed at the bottom, and the output pipe at the top of the contact column, which is also equipped with an additional filter element located above the contact element made of sintered granules between themselves.

 In this case, the working gas is called the ozone-air mixture, and the exhaust gas is the gas that has passed to the surface of the water basin after interacting with the water filling it.

 The operation of the prototype installation is based on the fact that the water to be ozonized enters the lower part of the contact column, partially filled with contact elements, and passes through the pores and intergranular cavities of these elements together with the ozone-air mixture, also supplied from the bottom of the contact column areas for the placement of contact elements. As it rises, ozone oxidizes impurities - organic and inorganic in water, converts them into an insoluble form, contributing to the precipitation. Thus, water is purified from unwanted impurities.

 So, the disadvantage of the prototype [3] is the deterioration of the following characteristics: energy consumption, environmental friendliness, reliability, cost, size.

 Accordingly, the required technical result consists in increasing the environmental friendliness and reliability of the installation, as well as reducing its energy consumption, cost and dimensions.

 The drawing shows a diagram of the proposed installation according to claim 1 of the formula.

The drawing uses the following conventions of the constituent elements:
1 - contact column
2 - input fitting
3 - output fitting
4 - inlet pipe
5 - outlet pipe
6 - pump
7 - compressor
8 - ozone-air mixture generation unit
9 - contact element.

The disadvantages of the prototype are eliminated in the proposed installation, which is significantly improved taking into account
- compliance with the regime of countercurrent water and finely dispersed ozone-air mixture;
- a sharp increase in the specific contact surface of the gas and liquid phases.

 The proposed installation contains a contact column with inlet / outlet fittings for the inlet / outlet of the working / exhaust gas and inlet / outlet nozzles for input / output of the source / ozonated water into and out of the contact column, as well as a pump connected to the inlet of the contact column, a compressor, the output of which is connected to the input of the ozone-air mixture generation unit, the output of which is connected to an inlet fitting located at the bottom of the contact column partially filled with contact elements, h coincides with the essential features of the prototype.

 In addition, the inlet pipe is located in the upper part of the contact column, the outlet pipe is located in the lower part of the contact column, and the filling height, the size of the contact elements, as well as the ratio of water and gas flow rates are selected taking into account the operation of the contact column in the foaming mode.

 In addition, the contact column is filled with contact elements in the form of rings.

 In addition, the contact column is filled with contact elements in the form of Raschig rings.

In addition, the ratio of water consumption V _in and gas V _g selected satisfying the following proportions: V _in : V _g = (0.05-0.5): 1.

 In addition, the size of the contact elements increases as they move away from the walls of the contact column.

 In addition, the size of the contact elements increases as they move away from the bottom of the contact column.

 In addition, the size of the contact elements increases as they move away from the bottom of the contact column.

 In addition, the surface of the contact elements has the catalytic properties of oxidation of impurities by ozone.

 The principle of operation of the proposed installation is as follows.

 In the contact column filled with contact elements, the source water is supplied from above, and the ozone-air mixture is supplied from below. In the volume filled with contact elements, the gas and liquid phases form a heterogeneous medium due to dynamic interaction, passing into a foam-like state. Moreover, the contact surface of the phases in the gas-liquid system increases by several orders of magnitude, which significantly increases the efficiency of the process of dissolving the ozone contained in the ozone-air mixture in water (usually not more than 1.5-5%). In addition, the method of countercurrent gas and liquid phases also contributes to a more efficient dissolution of ozone in water. In this case, the dynamic equilibrium of the diffusing flows of ozone from water to gas and back from gas to water is shifted in the upper part of the column towards the latter. Accordingly, gas bubbles in the upper part of the column have a low concentration of ozone, which reduces its leakage to the outlet (with exhaust gas). At the same time, there is no need for energy costs for the destruction of the ozone passing to the exit, as it had to be done in the prototype for environmental reasons.

So, the proposed installation for water saturation with ozone, containing a contact column with inlet / outlet fittings for the inlet / outlet of the working / exhaust gas and inlet / outlet pipes for input / output of water into and out of the contact column, respectively, as well as a pump connected to the inlet a nozzle of the contact column, a compressor, the output of which is connected to the input of the ozone-air mixture generation unit, the output of which is connected to an input fitting located at the bottom of the contact column, partially filled with contact elements entami
characterized in that the inlet pipe is located in the upper part of the contact column, the outlet pipe is located in the lower part of the contact column, the filling height, the size of the contact elements, as well as the ratio of water to gas flow rates are selected taking into account the operation of the contact column in foaming mode.

 The installation according to claim 1, characterized in that the contact column is filled with contact elements in the form of rings, for example, such as Raschig rings, is also proposed.

Also proposed is the installation according to claim 1, characterized in that the ratio of the flow rates of water V _in and gas V _g selected satisfying the following proportions: V _in : V _g = (0.05-0.5): 1.

 Also, the installation according to claim 1, characterized in that the size of the contact elements increases as they move away from the walls of the contact column.

 Also proposed is the installation according to claim 1, characterized in that the size of the contact elements increases as they move away from the bottom of the contact column.

 Also proposed is the installation according to claim 1, characterized in that the cross section of the contact column decreases as it moves away from the bottom of the contact column.

 Also, the installation according to claim 1, characterized in that the surface of the contact elements has the catalytic properties of the oxidation of impurities by ozone.

 Next, we show that it is thanks to the significant differences of the proposed installation that the required technical result is provided.

The fact that the inlet pipe is located in the upper part of the contact column, the outlet pipe is located in the lower part of the contact column, and the filling height, the size of the contact elements, as well as the ratio of water to gas flow rates are selected taking into account the operation of the contact column in the foaming mode, leads to a number advantages of the proposed:
- to increase the contact surface of the gas-liquid phase interface. In this case, the intensity of the mass transfer process, proportional to the gas-liquid interface, increases accordingly;
- to an additional increase in the rate of mass transfer, taking into account the counterflow of the liquid and gas phases reacting among themselves;
- to reduce the energy consumption of the installation, taking into account the fact that in the foaming mode, the specific (i.e., reduced to a unit mass of liquid) contact surface of the liquid and gas phases is so developed that the contact area required for a given mass transfer rate is provided with a significantly lower mass water than required in the prototype.

 In addition, in the prototype, water is supplied from bottom to top through a layer of contact elements that create an additional transitional attenuation, which leads to additional energy consumption for pumping water. In the proposed installation, water is supplied to the upper part of the contact column through a free channel (pipeline) that does not require increased pressure and, accordingly, increased energy consumption. The passage of the layer of contact elements then occurs under the action of gravity, without additional energy consumption.

 The fact that the contact column is filled with contact elements in the form of rings also increases the efficiency of the mass transfer process and reduces energy consumption, taking into account the fact that this type of contact element forms a sufficiently developed surface and at the same time has a fairly small transitional aerodynamic damping.

 The fact that the contact column is filled with contact elements in the form of commercially mastered and widespread component parts, for example, such as Rashig rings, reduces the cost of installation, since the use of finished products eliminates the cost of developing a new product.

The fact that the ratio of water consumption V _in and gas V _{g is} selected satisfying the following proportion: V _in : V _g = (0.05-0.5): 1, provides the formation of a foam formation mode.

 The fact that the size of the contact elements increases as they move away from the walls of the contact column increases the uniformity of the distribution of the gas stream over the cross section of the column. This increases the efficiency of the process of mass transfer of the reacting phases.

 The fact that the size of the contact elements increases as they move away from the bottom of the contact column also increases the efficiency of the mass transfer process, since it evens out the speed of the mass transfer process in the vertical direction. Indeed, the rate of transition of ozone to water in the lower part of the column is reduced taking into account the influence of Henry's law, since the water in the lower part of the column contains a higher concentration of ozone than the water in the upper part of the column, which has not yet had time to react with ozone. To compensate for this decrease in the rate of dissolution of ozone in the lower part of the column, it is advisable to increase the surface area of the contact elements, making these elements smaller. This leads to a finer dispersion of the formed foam and, accordingly, to an increase in the surface area of the interface of the reacting phases.

 The fact that the surface of the contact elements has the catalytic properties of the oxidation of impurities by ozone leads to an increase in the efficiency of mass transfer processes. Moreover, the catalytic process can provide an accelerated transition of ozone to water, which will further increase the efficiency of the mass transfer process.

 This provides the above technical result.

 Thus, the proposed installation provides the required technical result - environmental friendliness and reliability of the installation are increased, the efficiency of mass transfer of liquid and gas is increased in it, and its energy consumption, cost and dimensions are reduced.

 Along with this, it is shown that the required technical result is indeed achieved due to the significant differences of the proposed installation.

 The experiments showed the feasibility of the proposed object of the invention.

Claims (6)

1. Installation for saturation of water with ozone, containing a contact column with inlet / outlet fittings for the inlet / outlet of the working / exhaust gas and inlet / outlet pipes for input / output of water into and out of the contact column, respectively, as well as a pump connected to the inlet a nozzle of the contact column, a compressor, the output of which is connected to the input of the ozone-air mixture generation unit, the output of which is connected to the input fitting located at the bottom of the contact column, partially filled with contact elements, I distinguish ayasya in that the inlet situated at the top of the contact tower, the outlet is placed at the bottom of the contact tower, and the ratio of V _{in the} water flow and gas V _g is selected to meet the following proportions: V _in: V _g = (0,05-0, 5): 1.  2. Installation according to claim 1, characterized in that the contact column is filled with contact elements in the form of rings.  3. Installation according to claim 1, characterized in that the contact column is filled with contact elements in the form of Raschig rings.  4. Installation according to claim 1, characterized in that the size of the contact elements increases as they move away from the walls of the contact column.  5. Installation according to claim 1, characterized in that the size of the contact elements increases as they move away from the bottom of the contact column.  6. Installation according to claim 1, characterized in that the surface of the contact elements has the catalytic properties of the oxidation of impurities by ozone.