RU2319954C1 - Electrode - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: electrode comprises insulated housing filled with electrolyte, rod mounted inside the housing, potential pickup mounted on the housing and connected with a tip, and ion-exchange diaphragm. The rod is made of silver and represents an electrode. The ion-exchanger diaphragm is pressed to the housing via the sealing spacer by means of clutch provided with perforation. The electrolyte is made of the saturated water solution of a mixture of potassium chloride and ethylene glycol in a ratio of 3:2-2:1.

EFFECT: enhanced reliability.

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Description

FIELD OF THE INVENTION

The invention relates to the protection against corrosion of underground metal structures, in particular to non-polarizable silver chloride electrodes for long-term comparison, and can be used to determine the danger of corrosion and the effectiveness of protection of underground metal structures.

State of the art

A non-polarizable reference electrode is known mainly for cathodic protection devices, comprising a housing in the form of a disk with a cavity on the side surface filled with filler in the form of a saturated solution of copper sulfate, mounted on bearings on an axis, ring-mounted electrodes mounted in the cavity, a contact rim, a collector collector, and conductors, while the cavity in the disk is made with a U-shaped profile, the contact rim is made in the form of conjugated curtains of durable fabric and a chamber of flexible flexible material with a hose ohm for connecting to the pneumatic line, and the camera is mounted on the middle protrusion of the housing, and the curtain is mounted on the extreme protrusions of the housing with the possibility of covering the camera.

In the electrode, the filler is made in the form of a spongy material (see ed. St. USSR No. 1689432, class C23F 13/00, G01N 27/30, publ. 07.11.1991).

The disadvantage of this reference electrode is the low reliability and quality of measurements.

Known equipment for determining the bias of the potential difference between the underground metal structure and the reference electrode, containing a voltmeter with an internal resistance of at least 20 kOhm per 1 V scale, which records or shows a copper-sulfate reference electrode, a steel reference electrode, with which measurements are taken at control points wells, pits, etc. contact method using recording or indicating devices, while the positive terminal of the measuring device is connected to the structure, the negative to the reference electrode, followed by processing the measurement results, and the difference between the measured potential of the structure and the value of its stationary potential is calculated by the formula

ΔU = U _rev -U _c,

where U _ISM is the least negative or most positive over the measurement period, the instantaneous potential difference between the structure and the copper-sulfate reference electrode;

U _c is the stationary potential of the structure.

(see. Unified system of protection against corrosion and aging. Underground structures. General requirements for protection against corrosion. GOST 9.602-89, Moscow).

The disadvantage of this equipment is its relatively low service life.

The closest in technical essence and the achieved positive effect and adopted by the authors for the prototype is a long-acting comparison electrode containing a non-conductive housing with a porous bottom filled with an electrolyte, a copper rod located in the housing and a potential sensor mounted on the housing, while it is equipped with an ion-exchange membrane mounted on the porous bottom of the body, and the electrolyte contains a saturated solution of copper sulfate in a mixture of water and ethylene glycol in a ratio of 3: 2-2: 1.

The electrode uses an ion-exchange membrane obtained by rational graft copolymerization of acrylic or methacrylic acid in an amount of 100-170% on a biaxially oriented polypropylene film (see ed. St. USSR No. 1601199, class C23F 13/00, publ. 23.10.1990) .

The disadvantage of this electrode is a significant reduction in service life when used in soils with a high content of calcium and chlorine, which is proved by the results of many years of operation. This occurs as a result of the replacement of CuSO ₄ ions by ions of more active Ca and Cl, which leads to an irreversible change in the electrode potential. In addition, the potential of silver chloride electrodes is more stable, in comparison with the potential of copper-sulfate reference electrodes, which is why when monitoring the potentials of copper-sulfate electrodes, a silver chloride electrode is used as a reference.

Disclosure of invention

The task of the invention is to develop a non-polarizable silver chloride reference electrode with reliability and quality measurements.

The technical result that can be achieved using the present invention is to improve the reliability and quality of measurements due to a silver chloride comparison electrode of long duration, suitable for installation in the ground during work on the electrochemical protection of underground metal structures from corrosion, which has a stable potential and is not critical to the composition of the soil in which the electrode is installed.

The technical result is achieved using a non-polarizing silver chloride comparison electrode containing a non-conductive case filled with an electrolyte, a rod located in the case, and a potential sensor on the case, which are connected by a conductor to the tip, an ion-exchange membrane, while the rod is made of silver with an insoluble coating of silver chloride and which is the electrode, and the ion-exchange membrane is pressed through the gasket to the housing by means of a perforated coupling, When in use, an electrolyte, which housing is filled electrode comprises a saturated solution of potassium chloride in a mixture of water and ethylene glycol in a ratio of 3: 2-2: 1.

The technical result that can be obtained by carrying out the invention is achieved as follows. The electrode body is filled with an electrolyte, which includes distilled water, ethylene glycol and potassium chloride (KCl), while the KCl content provides saturation of the solution with the release of free crystals of KCl · 5H ₂ O. In the central part of the body, an electrode is installed, which is a silver rod having insoluble coating of silver chloride AgCl.

The essential features of the claimed invention are as follows.

The non-polarizing silver chloride comparison electrode contains a non-conductive case filled with an electrolyte, which includes distilled water, ethylene glycol and potassium chloride (KCl), while the KCl content should ensure saturation of the solution, with the release of free crystals of KCl · 5H ₂ O. In the central part The body is equipped with an electrode, which is a silver rod having an insoluble coating of silver chloride AgCl.

Unlike the prototype, the electrolyte with which the electrode body is filled consists of distilled water, ethylene glycol and potassium chloride, while the content of potassium chloride should ensure saturation of the solution, with the release of free crystals of KCl · 5H ₂ O.

The electrode is a silver rod having an insoluble AgCl silver chloride coating.

Brief Description of the Drawings

Figure 1 is given a silver chloride non-polarizable long-acting reference electrode, general view.

Figure 2 - scheme for measuring the potential difference.

Figure 3 - diagram of the measurement of polarization potential.

The implementation of the invention

A non-polarizing silver chloride comparison electrode 1 of long duration is installed directly in the ground 2 near the pipeline 3, while the comparison electrode 1 consists of a current-conducting case 4 filled with electrolyte 5, which includes distilled water, ethylene glycol and potassium chloride (KCl), with the content of KCl provides saturation of the solution with the release of free crystals of KCl · 5H ₂ O. The ratio of water and ethylene glycol is 2: 1. In the central part of the housing 4 of the reference electrode 1, a silver rod 6 is mounted, electrically connected by a copper conductor (not shown in FIG.) To the tip 7. An insoluble coating 8 of AgCl silver chloride is applied to the rod 6. To ensure ion exchange, while maintaining tightness, a homogeneous ion-exchange membrane 9 with a thickness of 30-60 μm is used on the basis of a biaxially oriented polypropylene film containing 150% radiation grafted methacrylic acid pressed through a rubber gasket 10 with a sleeve with perforation 11 to the housing 4, while the housing 4 of the reference electrode 1 has a potential sensor 12, electrically connected with a copper conductor with a tip 13. Conductors from a silver rod 6 and a potential sensor 12 from the tip and 7 and 13 are displayed on the ground surface for connecting measuring devices 14 and 15 via bus 16 connected to the conduit 3 in the production potential measurements.

Non-polarizable silver chloride comparison electrode of a long action works as follows.

A non-polarizing silver chloride comparison electrode 1 of long duration is installed in the soil 2 in the immediate vicinity of the underground structure, in particular the pipeline 3 connected to a conductor (not shown in FIG.), Which goes to the surface of the earth. To measure the potential difference between the conductor connected to the underground structure 3 and the tip 7 connected to the silver rod 3 of the reference electrode 1, a DC voltmeter 14 is connected having an input resistance of at least 20 kOhm / V at a measurement limit of 0-3 V or close to the specified measurement limit, and the positive terminal is connected to the conductor from the underground structure, the negative terminal of the voltmeter 14 is connected to the tip 7.

The polarization potential is measured in accordance with the circuit in figure 3.

The polarization potential measurements are carried out using devices containing a current chopper, for example 43313.1, ORION-IP01, while terminal “C” of device 1 is connected to a conductor from an underground structure 3, terminal “IE” is connected to a tip 7 connected by a conductor to a silver electrode rod comparison 1, and the terminal "VE" - to the tip 13 connected by a conductor to the potential sensor 14.

Example. Standard copper-sulfate electrodes for comparing long-term action with an ion-exchange membrane are placed in cuvettes of dielectric material, one of which contains a saturated aqueous solution of CaCl ₂ , the second cuvette is filled with sand, moistened with a solution of NaCl in distilled water. Silver chloride electrodes 1, assembled according to the drawing shown in Fig. 1, are placed in two cuvettes with the same composition. Within six months, the potentials of the electrodes are measured relative to the laboratory silver chloride electrode EVL-1M1 (TU-25-07-591-69). Upon completion of the tests (after 6 months), the potential of the copper-sulfate reference electrode located in the cuvette containing an aqueous solution of CaCl ₂ decreased by 73 mV relative to the initial value. The potential of the copper-sulfate reference electrode located in a cuvette with a sand moistened with a solution of NaCl in distilled water decreased by 27 mV. The potential of silver chloride electrodes throughout the entire test period ranged from plus 5 to minus 4 mV.

The present invention, in comparison with the prototype and other known technical solutions, allows to obtain a non-polarizing long-acting reference electrode that is not critical to the composition of the soil in which it is installed, having an increased service life, with high stability of the potential value.

Claims (1)

A non-polarizable silver chloride comparison electrode containing a non-conductive case filled with an electrolyte, a rod located in the case, and a potential sensor on the case, which are connected by conductors to the tips, and an ion-exchange membrane, the rod being made of silver with an insoluble coating of silver chloride, an ion-exchange membrane pressed through the gasket to the housing by means of a perforated coupling, and used as the electrolyte with which the electrode housing is filled Saturation of potassium chloride dissolved in a mixture of water and ethylene glycol in a ratio of 3: 2-2: 1.

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