SU1518308A1 - Method of treating waste water - Google Patents

Abstract

The invention relates to methods for electrochemical treatment of wastewater from mechanical impurities and petroleum products. The purpose of the invention is to increase the degree of purification. The wastewater treatment method includes electroflotation purification using a horizontal set of electrodes, the cathodes being made of various materials and placed in a decreasing order of gas evolution rate, which is determined by the calculation formula. 6 tab., 2 Il.

Description

The invention relates to the treatment of wastewater by electrochemical methods and can be used for the treatment of wastewater from petroleum products and mechanical impurities.

The purpose of the invention is to increase the degree of purification.

Figure 1 shows a water purification apparatus; in fig. 2 - the same, top view.

The invention is illustrated by the following examples.

Example 1. Water purification was carried out in an apparatus (Fig. 1), which is a rectangular Plexiglas body 1. At the bottom of the apparatus there is a graphite electrode 2 (anode), above the anode there are alternating cathodes made of metal wire of the same diameter 0.8 mm, and the electrodes 3 are made of silver, 4 is made of copper, 5 is made of aluminum, 6 is made of lead, then this the sequence is repeated. Cathodes of the same metal are connected by external tires.

Experiments were performed according to the following method.

Contaminants were introduced into the water, which were used to take bentonite and liquid paraffin. The latter is a pure hydrocarbon liquid with Newtonian properties, which is used as a model for oil. The dispersed system was prepared by mixing water with a high-speed engine. The prepared dispersion system was cleaned in the described static electrofloter. Purification was carried out for 4 minutes so that the number of contaminants after purification was still significant and it would be possible to compare the results of different experiments. After the electroflotter was turned off, the clarified water was collected and analyzed on a photocolorimeter. The content of contaminants is determined by the appropriate calibration curve,

Five experiments were carried out for each type of water and pollution. In the 1st experiment

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The flotation was carried out for 1 min sequentially on each of the electrodes 3-6 the first wiHVTy - on the silver electrode, the second - on the copper electrode, the third - on the aluminum electrode, the fourth - on the lead one. In this and other experiments, the condition of constant current density was observed. In the second experiment, flotation was conducted for 4 min on a silver electrode. In experiments 3–5, flotation was carried out independently on copper, aluminum and lead electrodes for 4 minutes.

The results of the experiments are given in table. 14.

From the above results it follows that electroflotation of water using a combination of different cathode materials in all cases has a positive effect.

Example 2. A model of waste water was prepared on a normal pore of sodium chloride. Vaseline oil and bentonite at a concentration of 1000 mg / dm were dispersed in water. In the control experiments (prototype), the current density from electrode to electrode was changed, according to the proposed method, electrodes were kept fixed at a current density on electrodes made of various materials: 1 - copper with silver coating, 2 - nickel, 3 - steel, 4 - tungsten, 5 - lead. Electrode materials were arranged in decreasing order of gas release rate (Table 6).

The results of the experiments are given in table .5.

From the above results it follows that a decrease in flow turbulization due to a decrease in size

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Floating puzzles of gas gives a positive, positive result both in terms of the quality of cleaning and energy consumption.

Compared with the known methods of wastewater treatment by electroflotation, the proposed method has new properties, namely: the regulation of the gaseous gas is made by selecting the cathode material, while avoiding an increase in the size of the gas bubbles, which is inevitable when the prototype current density decreases. The proposed method allows to increase the depth of cleaning, which is extremely important from the standpoint of nature conservation.

Claims (1)

Invention Formula The method of sewage treatment by electroflotation in an apparatus with horizontally located cathodes and anodes, characterized in that, in order to increase the degree of purification, the process is carried out using cathodes made of various metals and arranged in the course of water movement in order to ensure gas velocity of V, defined by the formula RT,. E + a + bl i. . I - J V F. Z-P ( and where R is a universal gas constant; T is the temperature. TO; F is the Farade number; Z is the valence; P - pressure, Pa; standard electrode potential, V; a, b - Tafel coefficients; J is the current density, and is the voltage drop, V, Table 1 Raspor: 1 H.NaCl +1 N.NS, Zlgr reader: bentonite. , + Si- | + L1 + Pb 1 + U1 + 1 980 + 890НООО- -1060 Li41030 980 1000 10 L O on , R and 1200, 800, 500, 500, 500, 500, 200, 100500, 500 10.1 ... 15.25.8 ... 8.3 Average 12.7 Average 6.9 17.6 ... 21.213.9 ... 16.5 Average 19.1 Average 15.4 28.8; 12.8; 5.0; 4.0; 5.6; 7.2; 0.8; - 0.8; 0.2; Amount A 7.6 10.2; 9.4 Amount 36.4 1.34 1.34 1.26 0.93 0.85 0.93 0.93 1.14 0.87 0.87 0.72 0.72 0.66 0.58 0.58 0.62 0, 62 0.59 0.56 1.55 1.41 0.70 0.10 0, 10 0.12 0.10 0.09 0.20 0.20 0.21 0.13 0.13 0.12 0.12 0.11 0.08 0.08 0.10 0, 10 0, 10 0, 10 0, 14 0.12 0, 11 -0.13 1.69 -0.76 0.24 -1.66 -0.14 0.15 -0.60 1.80 0.52 -0.44 -0.04 -0.20 0.80 2.00 -0.28 1.80 -0.25 0.26 -1.63 0.85 1.69 Table 5 Average 15, 4.0; 5.6; 7 10.2; 9.4 Amount 36.4 Hablitsab 0,35 0,08 0,42 0,24 0,37 0,37 0,19 0,39 0,13 0,65 0,44 0,27 0,28 0,68 0,22 0,44 0, 15 0.44 0, 13 0.47 0.24 0.46 1.94 8.50 1.62 2.83 2.73 1.83 3.58 1.74 5.23 1.05 1.54 2.51 2.42 one 3.09 1.55 4.53 1.55 5.23 1.45 2.83 1.48 5ISIfi-jOR6 T b: i and li a Solution: 1 H.NaCl + 1 H.NaOH. Contaminant; bsntoppt. Solution: 1 H.NaCl. Loader: bentonite. Solution: 1 H.NaCl + 0.1% surfactant type ML-72 (to stabilize elution). Contaminant: liquid paraffin. u + Al + Pb 1 + 1 + 1 + 11163 + 964 + 1020 + 990 41,140 A1049 41011 41010 Table 3 Table 4 hOF x x x x x x jii XX XXXXX XX AXXxX 5 h A -o - o-o-o with / g. / 5 6 / / / L /