Electrochemical water treatment. Electrolysis

When a direct electric current is passed through the electrolyte, chemical reactions occur on the electrodes. This process is called electrolysis, which means the decomposition (of substances) with the help of electricity.

In sec. 8.1, it was indicated that an electrolyte is such a liquid that, when an electric current is passed through it, undergoes a chemical reaction. The electrolyte may be a molten salt, such as lead(H) bromide, or an aqueous solution of some acid, base, or salt.

Electric current is supplied to the electrolyte using electrodes - wire conductors, metal rods or plates that make electrical contact with the electrolyte. The negatively charged electrode is the cathode and the positive electrode is the anode. Electrodes that do not enter into chemical reactions when in contact with electrolytes and when an electric current is passed through them are called inert electrodes. Inert electrodes include graphite and platinum.

IONIC THEORY OF ELECTROLYSIS

According to this theory, the passage of a direct electric current through the electrolyte is carried out with the help of ions. At the electrodes, electrons are transferred to or from ions. Therefore, the processes occurring on the electrodes can be considered as reducing or oxidizing half-reactions. Thus, electrolysis is a redox process.

An oxidative half-reaction always takes place at the anode. In this reaction, anions lose electrons and are discharged, turning into neutral particles. Therefore, the anode acts as a sink for electrons from anions.

A reduction half-reaction always occurs at the cathode. Here, cations acquire electrons and discharge, turning into neutral particles. Therefore, the cathode acts as a source of electrons for cations.

The electrolysis of molten lead(H) bromide consists of two half-reactions:

1) bromide ions are discharged at the anode. (The equation for this half-reaction has

2Вg-(l.) \u003d Vg2 (g.) + 2e-

This half-reaction is an oxidation.)

2) lead ions are discharged at the cathode. (The equation for this half-reaction is:

Pb2+(solid) + 2e- = Pb(l.)

This half-reaction is a reduction.)

It should be noted that the reactions occurring at the anode and cathode in each particular system are predetermined by the polarity of the current source in the external electrical circuit. The negative pole of an external current source (battery) supplies electrons to one of the electrodes of the electrolytic cell. This causes a negative charge of this electrode. It becomes the cathode. Since this electrode is negatively charged, it in turn causes an electrode reaction in which electrons are consumed. Thus, the recovery process is carried out on this electrode. At the other electrode, electrons flow from the electrolytic cell back into the external circuit, making this electrode the positive electrode. So, this electrode plays the role of the anode. Due to its positive charge, a reaction occurs on it, which is accompanied by the release of electrons, i.e. oxidation.

A schematic representation of the entire electrolysis process is shown in fig. 10.6.

The formation of an insoluble substance as a result of a chemical reaction is only one of the conditions for obtaining a colloidal solution. Another equally important condition is the inequality of the starting materials taken into the reaction. The consequence of this inequality is the limitation of the growth of the size of particles in colloidal solutions, which would lead to the formation of a coarsely dispersed system.

Let us consider the mechanism of formation of a colloidal particle using the example of the formation of a silver iodide sol, which is obtained by the interaction of dilute solutions of silver nitrate and potassium iodide.

AgNO 3 + KI \u003d AgI + KNO 3

Ag + + NO 3 ¯ + K + + I ¯ = AgI ↓ + NO 3 ¯ + K +

Insoluble neutral molecules of silver iodide form the core of a colloidal particle.

At first, these molecules combine in disorder, forming an amorphous, loose structure, which gradually turns into a highly ordered crystalline structure of the core. In the example we are considering, the core is a silver iodide crystal, consisting of a large number (m) of AgI molecules:

m - the core of the colloidal particle

An adsorption process takes place on the surface of the nucleus. According to the Peskov-Fajans rule, ions that are part of the particle core are adsorbed on the surface of the nuclei of colloidal particles, i.e. silver ions (Ag +) or iodine ions (I -) are adsorbed. Of these two types of ions, those that are in excess are adsorbed.

So, if a colloidal solution is obtained in an excess of potassium iodide, then iodine ions will be adsorbed on particles (nuclei), which complete the crystal lattice of the nucleus, naturally and firmly entering its structure. In this case, an adsorption layer is formed, which gives the nucleus a negative charge:

Ions adsorbed on the surface of the nucleus, giving it an appropriate charge, are called potential-forming ions.

At the same time, oppositely charged ions are also in solution, they are called counterions. In our case, these are potassium ions (K +), which are electrostatically attracted to the charged nucleus (the charge value can reach I c). Part of the K + counterions is strongly bound by electric and adsorption forces and enters the adsorption layer. A core with a double adsorption layer of ions formed on it is called a granule.

(m . nI - . (n-x) K + ) x - (granule structure)

The remaining part of the counterions (let us denote them by the number "x K +") forms a diffuse layer of ions.

The core with adsorption and diffusion layers is called a micelle. :

(m . nI -. (n-x) K + ) x - . x K + (micelle structure)

When a constant electric current is passed through a colloidal solution, the granules and counterions will move towards the oppositely charged electrodes, respectively.

The presence of the same charge on the surface of sol particles is important. factor in its sustainability. The charge prevents sticking and enlargement of particles. In a stable disperse system, particles are kept in suspension, i.e. no precipitation of the colloidal substance occurs. This property of sols is called kineti chesky stability.

The structure of micelles of the silver iodide sol obtained in excess of AgNO 3 is shown in Fig. 3. 1a, in excess of KCI - 1b .

Fig.1.5. The structure of micelles of silver iodide sol obtained in excess:

a) silver nitrate; b) potassium chloride.

Electrolysis- a redox process that occurs on electrodes when a direct electric current is passed through an electrolyte solution or melt. In an electrolyzer, electrical energy is converted into the energy of a chemical reaction.

Cathode (-) – negative electrode at which reduction occurs during electrolysis.

Anode (+) – the positive electrode at which oxidation occurs during electrolysis.

Unlike electrolysis, in a galvanic cell, reduction occurs on a positively charged cathode, and oxidation occurs on a negatively charged anode.

In electrolysis, inert (insoluble) and active (consumable) anodes can be used. The active anode, being oxidized, sends its own ions into the solution. An inert anode is only an electron transmitter and does not change chemically. Graphite, platinum, and iridium are usually used as inert electrodes.

During the electrolysis of melts and electrolyte solutions, the ions formed during their dissociation (under the influence of temperature or water) - cations (Kt n +) and anions (An m -) move, respectively, to the cathode (-) and anode (+). Then, at the electrodes, electrons are transferred from the cathode to the cation, and the anions donate electrons to the anode.

Quantitatively, electrolysis is described by two Faraday laws.

I Faraday's law: the mass of the substance released during electrolysis is proportional to the amount of electricity that has passed through the electrolyzer:

m = k I∙τ = k∙Q ,

Where I– current strength; τ – current flow time; Q = I∙τ- the amount of electricity; k- coefficient of proportionality, the value of which depends on the chosen system of units (if Q= 1 C, then m = k).

The mass of a substance released during the passage of 1 C of electricity is called electrochemical equivalent.

II Faraday's law: with the same amount of electricity passed through the electrolyte, the number of gram equivalents of the electrolysis products is the same.

To release one equivalent of any substance on the electrode, it is necessary to spend the same amount of electricity, equal to Faraday constant F= 96485 C/mol. Indeed, one equivalent of a substance contains N A = 6.02322∙10 23 particles, and in order to restore such a number of singly charged ions on the cathode, it is necessary to spend the amount of electricity:

F = N A∙ ē = 6.02322∙10 23 particles/mol ∙ 1.6021∙10 –19 C = 96485 C/mol,

where is the electron charge ē = 1.6021∙10 –19 Cl.

Generalizing both Faraday's laws, it is possible to write down.

Electroactivated water solutions - catholytes and anolytes can be used in agriculture, to increase plant productivity, in animal husbandry, medicine, for water disinfection and for domestic purposes. Electrochemical water treatment includes several electrochemical processes associated with the transfer of electrons, ions and other particles in a constant electric field (electrolysis, electrophoresis, electroflotation, electrocoagulation), the main of which is water electrolysis. This article introduces the reader to the main processes underlying the electrolysis of water.

Introduction

The phenomenon of electrochemical activation of water (EAW) is a combination of electrochemical and electrophysical effects on water in a double electric layer (DEL) of electrodes (anode and cathode) during non-equilibrium charge transfer through the DEL by electrons and under conditions of intensive dispersion in the liquid of the resulting gaseous products of electrochemical reactions. There are four main processes in the ECA process:

- electrolytic decomposition of water (electrolysis) due to redox reactions on the electrodes, caused by an external constant electric field;

- electrophoresis - the movement in an electric field of positively charged particles and ions to the cathode, and negatively charged particles and ions to the anode;

- electroflotation - the formation of gas floccules and aggregates consisting of finely dispersed gas bubbles (hydrogen at the cathode and oxygen at the anode) and coarsely dispersed water impurities;

- electrocoagulation - the formation of colloidal aggregates of particles of the precipitated dispersed phase due to the process of anodic dissolution of the metal and the formation of metal cations Al 3+ , Fe 2+ , Fe 3+ under the influence of a constant electric field.

As a result of water treatment with direct electric current, at potentials equal to or exceeding the water decomposition potential (1.25 V), water passes into a metastable state, characterized by abnormal values ​​of electron activity and other physico-chemical parameters (pH, Eh, ORP, electrical conductivity). The passage of a constant electric current through the volume of water is accompanied by electrochemical processes, as a result of which redox reactions occur, leading to the destruction (destruction) of water pollution, coagulation of colloids, flocculation of coarse impurities and their subsequent flotation.

The phenomenon of electrochemical activation of water is a combination of electrochemical and electrophysical effects on water in a double electric layer of electrodes during nonequilibrium charge transfer.

Electrochemical treatment is used for clarification and discoloration of natural waters, their softening, purification from heavy metals (Cu, Co, Cd, Pb, Hg), chlorine, fluorine and their derivatives, for the treatment of wastewater containing petroleum products, organic and organochlorine compounds, dyes , surfactants, phenol. The advantages of electrochemical water purification is that it allows you to adjust the values ​​of the pH value and the redox potential E h , which determines the possibility of various chemical processes in water; increases the enzymatic activity of activated sludge in aeration tanks; reduces resistivity and improves conditions for coagulation and sedimentation of organic sediments.

In 1985, EXHAV was officially recognized as a new class of physical and chemical phenomena. Order of the Government of the Russian Federation of January 15, 1998 No. VCh-P1201044 gave recommendations to ministries and departments to use this technology in medicine, agriculture, and industry.

water electrolysis

The main stage of electrochemical water treatment is water electrolysis. When a constant electric current is passed through water, the entry of electrons into the water at the cathode, as well as the removal of electrons from the water at the anode, is accompanied by a series of redox reactions on the surfaces of the cathode and anode. As a result, new substances are formed, the system of intermolecular interactions changes, the composition of water, including the structure of water. A typical installation for electrochemical water treatment consists of a water treatment unit 1, an electrolyzer 2, and a water treatment unit 3 after electrochemical treatment (Fig. 1).

In some electrochemical water treatment plants, preliminary mechanical water purification is provided, which reduces the risk of clogging of the electrolytic cell with coarse impurities with high hydraulic resistance. A block for mechanical water purification is necessary if, as a result of electrochemical treatment, water is saturated with coarse impurities, for example, flakes of metal hydroxides (Al (OH) 3, Fe (OH) 3, Mg (OH) 2) after electrocoagulation. The main element of the installation is an electrolyzer, consisting of one or more electrolysis cells (Fig. 2).

The electrolysis cell is formed by two electrodes - a positively charged anode and a negatively charged cathode, connected to different poles of a direct current source. The interelectrode space is filled with water, which is an electrolyte capable of conducting electric current. As a result of the operation of the device, there is a transfer of electric charges through a layer of water - electrophoresis, that is, the migration of polar particles, charge carriers - ions, to electrodes of the opposite sign.

When a constant electric current is passed through water, the entry of electrons into the water at the cathode, as well as the removal of electrons from the water at the anode, is accompanied by a series of redox reactions on the surfaces of the cathode and anode.

In this case, negatively charged anions move to the anode, and positively charged cations move to the cathode. At the electrodes, charged ions lose their charge, depolarize, turning into decay products. In addition to charged ions, polar particles of various dispersity participate in electrophoresis, including coarse particles (emulsified particles, gas bubbles, etc.), but charged ions with the highest mobility play the main role in the transfer of electrochemical charges. Polar particles include polar particles from among water impurities and water molecules, which is explained by their special structure.

The central oxygen atom, which is part of the water molecule, which has a greater electronegativity than hydrogen atoms, draws electrons towards itself, giving the molecule asymmetry. As a result, the electron density is redistributed: the water molecule is polarized, taking on the properties of an electric dipole having a dipole moment of 1.85 D (Debye), with positive and negative charges at the poles (Fig. 3).

The products of electrode reactions are neutralized aqueous impurities, gaseous hydrogen and oxygen formed during the electrolytic destruction of water molecules, metal cations (Al 3+, Fe 2+ , Fe 3+) in the case of using metal anodes made of aluminum and steel, molecular chlorine, etc. In this case, gaseous hydrogen is generated at the cathode, and oxygen is generated at the anode. The composition of water contains a certain amount of hydronium ion H 3 O +, which depolarizes on the cathode surface with the formation of atomic hydrogen H:

H 3 O + + e - → H + H 2 O.

In an alkaline environment, H 3 O + is absent, but water molecules are destroyed, accompanied by the formation of atomic hydrogen H - and hydroxide OH -:

H 2 O + e - → H + OH -.

Reactive hydrogen atoms are adsorbed on the surfaces of cathodes and, after recombination, form molecular hydrogen H 2 , which is released from water in gaseous form:

H + H → H 2.

At the same time, atomic oxygen is released at the anodes. In an acidic environment, this process is accompanied by the destruction of water molecules:

2H 2 O - 4e - → O 2 + 4H +.

In an alkaline environment, OH hydroxide ions always serve as a source of oxygen formation, moving under the action of electrophoresis on the electrodes, from the cathode to the anode:

4 OH - → O 2 + 2 H 2 O + 4 e -.

The normal redox potentials of these reactions are +1.23 and +0.403 V, respectively, but the process proceeds under conditions of some

overvoltage. The electrolysis cell can be considered as a generator of the above products, some of which, entering into chemical interaction with each other and with water contaminants in the interelectrode space, provide additional chemical water purification (electroflotation, electrocoagulation). These secondary processes do not occur on the surface of the electrodes, but in the volume of water. Therefore, unlike electrode processes, they are designated as volumetric. They are initiated by an increase in water temperature during electrolysis and an increase in pH during cathodic destruction of water molecules.

Distinguish between cathodic and anodic oxidation. During cathodic oxidation, molecules of organic substances, being sorbed on cathodes, accept free electrons, are restored, transforming into compounds that are not contaminants. In some cases, the recovery process takes place in one stage:

R + H + + e - → RH, where R is an organic compound; RH is the hydrated form of the compound and is not a contaminant.

In other cases, cathodic reduction takes place in two stages: at the first stage (I), the organic molecule is converted into an anion, at the second (II), the anion is hydrated by interacting with a water proton:

R + e - → R - , (I) R - + H + → RH. (II)

Distinguish between cathodic and anodic oxidation. During cathodic oxidation, molecules of organic substances, being sorbed on cathodes, accept free electrons and are reduced.

Cathodes made of materials that require a high overvoltage (lead, cadmium) allow, at a high cost of electricity, to destroy organic molecules and generate reactive free radicals - particles that have free unpaired electrons (Cl*, O*, OH*) in the outer orbits of atoms or molecules , NO*2, etc.). The latter circumstance gives free radicals the property of reactivity, that is, the ability to enter into chemical reactions with aqueous impurities and destroy them.

RH → R + H + + e - .

Anodic oxidation of organic compounds often leads to the formation of free radicals, the further transformations of which are determined by their reactivity. The processes of anodic oxidation are multistage and proceed with the formation of intermediate products. Anodic oxidation reduces the chemical stability of organic compounds and facilitates their subsequent degradation during bulk processes.

In volumetric oxidative processes, a special role is played by the products of water electrolysis - oxygen (O 2), hydrogen peroxide (H 2 O 2) and oxygen-containing chlorine compounds (HClO). In the process of electrolysis, an extremely reactive compound is formed - H 2 O 2, the formation of molecules of which occurs due to hydroxyl radicals (OH *), which are the products of discharge of hydroxyl ions (OH-) at the anode:

2OH - → 2OH* → H 2 O 2 + 2e -, where OH* is a hydroxyl radical.

The reactions of interaction of organic substances with oxidizing agents proceed for a certain period of time, the duration of which depends on the value of the redox potential of the element and the concentration of the reacting substances. As the concentration of the pollutant decreases and the concentration of the pollutant decreases, the oxidation process decreases.

The rate of the oxidation process during electrochemical treatment depends on the temperature of the treated water and pH. In the process of oxidation of organic compounds, intermediate products are formed that differ from the initial one both in resistance to further transformations and in toxicity indicators.

The sources of active chlorine and its oxygen-containing compounds generated in the electrolyzer are chlorides in the treated water and sodium chloride (NaCl), which is introduced into the treated water before electrolysis. As a result of anodic oxidation of Cl– anions, gaseous chlorine Cl 2 is generated. Depending on the pH of the water, it either hydrolyzes to form hypochlorous acid HOCl or forms hypochlorite ions ClO - . The equilibrium of the reaction depends on the pH value.

At pH = 4-5, all chlorine is in the form of hypochlorous acid (HClO), and at pH = 7, half of the chlorine is in the form of hypochlorite ion (OCl -) and half is in the form of hypochlorous acid (HClO) (Fig. 4). The mechanism of interaction of hypochlorite ion (ClO -) with the oxidized substance is described by the following equation:

ClO - + A = C + Cl, where A is the oxidizable substance; C is an oxidation product.

The electrochemical oxidation of organic compounds with hypochlorithione (ClO -) is accompanied by an increase in the redox potential Eh, which indicates the predominance of oxidative processes. The growth of Eh depends on the ratio of the concentration of active chlorine in the interelectrode space to the content of organic impurities in water. As cleaning and reducing the amount of pollution, this ratio increases, which leads to an increase in Eh, but then this indicator stabilizes.

The amount of the substance that reacted on the electrodes when passing a direct electric current according to Faraday's law is directly proportional to the current strength and processing time:

G = AI cur τ, (1)

where A is the electrochemical equivalent of the element, g/(A⋅h); I cur - current strength, A; τ is the processing time, h. The electrochemical equivalent of the element is determined by the formula:

A = M / 26.8z , (2)

where M is the atomic mass of the element, g; z is its valency. The values ​​of the electrochemical equivalents of some elements are given in Table. 1.

The actual amount of the substance generated during electrolysis is less than the theoretical one, calculated by formula (1), since part of the electricity is spent on heating water and electrodes. Therefore, the calculations take into account the current utilization factor η< 1, величина которого определяется экспериментально.

During electrode processes, there is an exchange of charged particles and ions between the electrode and the electrolyte - water. To do this, under steady-state equilibrium conditions, it is necessary to create an electric potential, the minimum value of which depends on the type of redox reaction and on the water temperature at 25 °C (Table 2).

The main parameters of water electrolysis include current strength and density, voltage within the electrode cell, as well as the speed and duration of water stay between the electrodes.

The voltages generated in the electrode cell must be sufficient for the occurrence of redox reactions on the electrodes. The voltage value depends on the ionic composition of water, the presence of impurities in water, for example, surfactants, current density (its strength per unit area of ​​the electrode), electrode material, etc. Other things being equal, the task of choosing an electrode material is to ensure that for the passage of oxidative recovery reactions on the electrodes, the required voltage was minimal, since this reduces the cost of electrical energy.

Some redox reactions are competing - they proceed simultaneously and mutually inhibit each other. Their flow can be controlled by changing the voltage in the electrolytic cell. So, the normal potential of the reaction of formation of molecular oxygen is +0.401 V or +1.23 V; with an increase in voltage to +1.36 V (normal potential for the reaction of molecular chlorine formation), only oxygen will be released at the anode, and with a further increase in the potential, both oxygen and chlorine will be released simultaneously, and chlorine will be released with insufficient intensity. At a voltage of about 4-5 V, the evolution of oxygen will practically cease, and the electrolytic cell will only generate chlorine.

Calculation of the main parameters of the water electrolysis process

The main parameters of water electrolysis include current strength and density, voltage within the electrode cell, as well as the speed and duration of water stay in the interelectrode space.

The current strength I cur is a value determined depending on the required performance for the generated product [A], is determined by the formula:

Icur=G/A tη , (3)

This formula is obtained by transforming formula (1) taking into account the current utilization factor η. The current density is its strength, related to the unit area of ​​the electrode [A / m 2], for example, the anode, is determined from the following expression:

i en = I cur / F en, (4)

where F an is the anode area, m 2 . The current density has the most decisive influence on the electrolysis process: that is, with an increase in current density, electrode processes are intensified and the surface area of ​​the electrodes decreases, but at the same time, the voltage in the electrolysis cell increases and, as a result, the entire energy intensity of the process. An increased increase in current density intensifies the release of electrolysis gases, leading to bubbling and dispersion of insoluble products of electrical water treatment.

With an increase in current density, the passivation of the electrodes also increases, which consists in blocking the incoming electrons by surface deposits of the anode and cathode, which increases the electrical resistance in the electrode cells and inhibits the redox reactions occurring on the electrodes.

Anodes are passivated as a result of the formation of thin oxide films on their surfaces, as a result of sorption of oxygen and other components on the anodes, which, in turn, sorb particles of aqueous impurities. On the cathodes, mainly carbonate deposits are formed, especially in the case of water treatment with increased hardness. For these reasons, the current density during the electrolysis of water should be set to the minimum under the conditions for the stable occurrence of the necessary redox reactions in the course of the technological process.

The residence time of water in the interelectrode space of the electrolyzer is limited by the time required to generate the required amount of electrolysis products.

The voltage in the electrode cell [V] is determined by the formula:

V i = i en ΔK g / χ R , (5)

where i an is the current density, A/m 2 ; D is the distance between the electrodes (width of the interelectrode channel), m; χ R is the electrical conductivity of water, 1/(Ohm⋅m); K g - coefficient of gas filling of the interelectrode space, usually taken K g \u003d 1.05-1.2.

Formula (5) does not take into account the electrical resistances of the electrode due to their low values, but during passivation, these resistances turn out to be significant. The width of the interelectrode channel is assumed to be minimal (3-20 mm) according to the conditions of non-clogging by impurities.

The specific electrical conductivity of water χ R depends on a number of factors, among which the most significant are temperature, pH, ionic composition and ion concentration (Fig. 5). With an increase in temperature, the electrical conductivity χ R increases, and the voltage decreases (Fig. 6). The minimum value of electrical conductivity corresponds to pH = 7. In addition, during the electrolysis process, the temperature and pH of water increase. If pH > 7, then we can expect a decrease in the specific electrical conductivity of water χ R , and at pH values< 7 удельная электропроводность воды χ R , наоборот, возрастает (рис. 5).

The specific electrical conductivity of natural waters of medium mineralization is 0.001-0.005 1 / (Ohm⋅m), urban wastewater is 10-0.01 1 / (Ohm⋅m) . During electrolysis, the electrical conductivity should be in the range of 0.1-1.0 1 / (Ohm⋅m) . If the source water has insufficient electrical conductivity, the salinity should be increased (Fig. 7). Usually, sodium chloride (NaCl) is used for this, the doses of which are determined experimentally and are most often 500-1500 mg / l (8-25 meq / l). Sodium chloride is not only convenient in terms of application and safety (storage, solution preparation, etc.), but in the presence of NaCl, electrode passivation slows down. Dissociating in water, NaCl saturates the water with chlorine anions Cl - and sodium cations Na + . Chlorine ions Cl - are small and, penetrating through passivating deposits to the anode surface, destroy these deposits. In the presence of other anions, especially sulfate ions (SO 2- 4 ), the depassivating effect of chloride ions (Cl -) is reduced. Stable operation of the cell is possible if the ions - Cl - make up at least 30% of the total number of anions. As a result of electrophoresis, sodium cations Na + move to the cathodes, on which hydroxide ions OH - are generated, and, interacting with the latter, form sodium hydroxide (NaOH), which dissolves carbonate deposits on the cathodes.

The power consumption [W] of the electrolytic cell is determined by the following relationship:

N consumption = η e I cur V e, (6)

where η e is the efficiency of the cell, it is usually taken η e = 0.7-0.8; I cur - current strength, A; V e - voltage on the electrolyzer, V.

The residence time of water in the interelectrode space of the cell is limited by the time required to generate the required amount of electrolysis products, as well as the duration of the corresponding volumetric reactions, and is determined experimentally.

The speed of water movement in the interelectrode space is set taking into account the conditions for the removal of electrolysis products and other impurities from the electrolyzer; in addition, turbulent mixing depends on the speed of water movement, which affects the course of volumetric reactions. Like the residence time of the water, the speed of the water is chosen based on experimental data.

To be continued.

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1. What was observed in Oersted's experiment?
a) Interaction of two parallel conductors with current.
b) Interaction of two magnetic needles.
c) Rotation of the magnetic needle near the conductor when current is passed through it.
d) The occurrence of an electric current in the coil when a magnet is placed in it.

2. How do two parallel conductors interact with each other if currents flow through them in the same direction?
a) are attracted. b) Repel. c) The force of interaction is zero. d) There is no correct answer.

3. When a direct electric current is passed through a conductor, a magnetic field arises around it. It is detected by the location of steel filings on a sheet of paper or by the turn of a magnetic needle located near the conductor. How can this magnetic field be moved in space?
a) Transfer of steel filings. b) By moving the magnet. c) The transfer of a conductor with current. d) The magnetic field cannot be moved.

4. How will the magnetic needles placed at points A and B inside the coil be located when the key K is opened?
a) Equally north pole to the right in the figure.
b) The same north pole to the left in the figure.
c) Arrows with north poles facing each other.
d) Arrows with south poles facing each other.

5. Why is the device of AC motors simpler than DC? Why are DC motors used in vehicles?

6. Determine the poles of the electromagnet.

7. Depict the magnetic field of currents and determine the direction of the magnetic field lines.

8. Determine the direction of the force acting on a current-carrying conductor placed in a magnetic field.

9. You have three items - "devices": a wooden block, two steel nails that are not attracted to each other, and a permanent magnet.
Three "black boxes" contain respectively: a magnet, two nails and a wooden block. What instruments and in what sequence is it better to use to find out what is in each of the boxes?

10. A DC motor consumes a current of 2 A from a source with a voltage of 24 V. What is the mechanical power of the motor if the resistance of its winding is 3 ohms? What is its K.P.D.?

Determine the direction of the current in the conductor, the cross section of which and the magnetic field are shown in Figure 1.

3. What direction does the current have in the conductor, the direction of the magnetic field lines of which is indicated by arrows (Fig. 3)?

5. In the direction of the magnetic lines of force shown in Figure 5, determine the direction of the circular current in the ring.

Electromagnetic waves arise: A. When electric charges move at a constant speed. B. With accelerated movement of electrical

B. Around stationary charges.

G. Around a fixed conductor through which a direct electric current passes.

D. Around a fixed charged metal plate

1. Electric current is called... A). the movement of electrons. B). orderly movement of charged particles. B). orderly movement of electrons. 2.

To create an electric current in a conductor, it is necessary... A). create an electric field in it. B). create electric charges in it. B). to separate electric charges in it. 3. What particles create an electric current in metals? A). Free electrons. B). positive ions. B). negative ions. ^ 4. What action of current is used in galvanometers? A. Thermal. B. Chemical. B. Magnetic. 5. The current strength in the circuit of the electric stove is 1.4 A. What electric charge passes through the cross section of its spiral in 20 minutes? A). 3200 cl. B). 1680 class B). 500 cl. ^ 6. In which diagram (Fig. 1) is the ammeter connected to the circuit correctly? A). 1. B). 2. B). 3. 7. When an electric charge equal to 6 C passes through the conductor, work of 660 J is performed. What is the voltage at the ends of this conductor? A). 110 V. B). 220 V. V). 330V. ^ 8. In which diagram (Fig. 2) is the voltmeter connected to the circuit correctly? A). 1. B). 2. 9. Two coils of copper wire of the same section have a length of 50 and 150 m, respectively. Which of them has more resistance and how many times? A). The first is 3 times. B). The second is 3 times. ^ 10. What is the strength of the current passing through a nickel wire 25 cm long and 0.1 mm2 in cross section if the voltage at its ends is 6 V? A). 2 A. B). 10 A. B). 6 A

1. In what units is the electric current strength measured? A. Ohm; B. J; W.W; G. A.

2. What actions are always manifested when an electric current passes through any medium?

A. Thermal; B. Magnetic; IN. Chemical; G. Light.

4. Determine the voltage under which the light bulb is, if when moving a charge of 10 C, work is done 2200 J.

5. Determine the resistance of section AB in the circuit shown in the figure.

6. Calculate the resistance of a nichrome wire with a length of 150 m and a cross-sectional area of ​​0.2 mm2.

7. A copper conductor with a cross section of 3.5 mm2 and a length of 14.2 m carries a current of 2.25 A. Determine the voltage at the ends of this conductor.

8. How many electrons pass through the cross section of the conductor in 35 s at a current strength of 16 A in it?

9. Determine the mass of an iron wire with a cross-sectional area of ​​​​2 mm2, taken to make a resistor with a resistance of 6 ohms.