RU2122047C1 - Nonpolarizable reference electrode - Google Patents

Abstract

FIELD: electrolytic technics. SUBSTANCE: electrode of invention can be applied when estimating corrosion danger and efficacy of protection of underground metallic structures. Electrode contains non-conducting casing with coupling. Casing is filled with electrolyte consisting of saturated cupric sulfate solution in water- ethylene glycol mixture. Into casing, a copper rod is imbedded. To improve accuracy of measuring potentials at different thickness of insulation coatings on underground structure, potential sensor is provided with removable attachment. To prolong lifetime and potential stability of reference electrode, at least two ion-exchange membranes are mounted on electrode casing. Coupling of casing has bottom with perforations against mechanical damages occurring when mounting and operating electrode. Removable attachment on potential sensor is mounted in dependence on thickness of insulation layer on underground structure. EFFECT: increased reliability and lifetime of electrode. 2 cl, 1 dwg

Description

 The invention relates to corrosion protection and can be applied in determining the danger of corrosion and the effectiveness of the protection of underground metal structures.

 The reference electrode is non-polarizable stationary (ENES), which according to the recommendations of the "Instructions for the Protection of Urban Underground Pipelines from Electrochemical Corrosion" (Collection of regulatory documents for workers of construction and operational organizations of the gas industry of the RSFSR. Protection of underground gas pipelines from corrosion, Section 2.2.9) is equipped with a control -measurement points on underground steel pipelines.

This reference electrode contains a copper rod, an electrolyte body, a ceramic porous diaphragm, an ion-exchange membrane. A potential sensor is mounted on the housing. The membrane and the diaphragm through the seal are pressed against the body using a sleeve. The copper rod is fixed in the plug installed in the housing cover. The electrode body is filled with an electrolyte, which includes distilled water, copper sulfate (CuSO ₄ • 5H ₂ O), ethylene glycol. The content of copper sulfate should ensure saturation of the solution with the release of free crystals of CuSO ₄ • 5H ₂ O (200-250 g / l). The device uses a homogeneous ion-exchange membrane with a thickness of 30-60 microns.

 The main disadvantage of this electrode is the presence of one membrane, which insufficiently prevents the osmotic penetration of ground water into the housing of the reference electrode or electrolyte from the electrode into the ground, which in the first case leads to the destruction of the membrane due to an increase in the internal pressure of the solution. With prolonged use, this leads to a decrease in the concentration of copper sulfate in the electrolyte solution below the saturation level after the complete dissolution of solid salt crystals and, accordingly, to a change in the electrode potential and a decrease in the accuracy of measuring the potentials of underground metal structures.

 The design of the potential sensor does not provide for the need to take into account the thickness of the anti-corrosion coating of an underground metal structure, and this affects the accuracy of measuring the potentials of the structure.

 The prototype is a long-acting comparison electrode that contains a non-conductive body with a porous bottom filled with an electrolyte. A copper rod is located in the housing. A potential sensor is mounted on the housing. The reference electrode is equipped with an ion-exchange membrane mounted on the porous bottom of the housing. 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 ion-exchange membrane was obtained by radiation grafted copolymerization of acrylic or methacrylic acid in an amount of 100-170% on a biaxially oriented polypropylene film (see autoswitch N 1601199, class C 23 F 13/00, "Long-acting reference electrode").

 Signs of the prototype, coinciding with the essential features of the claimed invention, the following. The long-acting comparison electrode contains a non-conductive housing, a sleeve, a copper rod located inside the housing. The housing is filled with an electrolyte from a saturated solution of copper sulfate in a mixture of water and ethylene glycol. The electrode also has an ion-exchange membrane. A potential sensor is mounted on the electrode housing.

 The reasons that impede the receipt of the required technical result for the prototype are as follows. The potential sensor of the prototype does not have a removable nozzle, which reduces the accuracy of measuring the potential of the protected structure with different thicknesses of the protective insulating coating of the pipeline. The electrode is equipped with one ion-exchange membrane, which insufficiently prevents the osmotic penetration of ground water into the housing of the reference electrode, which destroys the membrane by increasing the internal pressure of the solution. The housing coupling does not have a bottom with perforation, which can lead to mechanical destruction of the membrane when the electrode is installed in the ground, as well as during operation of the electrode.

 The technical result is an increase in the life of the reference electrode, the accuracy of measuring the potentials of underground metal structures with protective coatings when determining the danger of corrosion and monitoring the effectiveness of electrochemical protection, reducing the osmotic transfer of moisture into the housing of the reference electrode and protecting ion-exchange membranes from mechanical damage.

 The technical result is achieved by changing the design of the reference electrode.

 The technical result that can be obtained by carrying out the invention is achieved as follows. The potential sensor is equipped with a removable nozzle, which is installed depending on the thickness of the insulation layer in an underground metal structure. At least two ion-exchange membranes are additionally mounted on the housing of the reference electrode, and the bottom of the coupling mounted on the electrode body has perforations.

 The essential features of the claimed invention are as follows.

 The non-polarizable reference electrode contains a non-conductive housing filled with an electrolyte from a saturated solution of copper sulfate in a mixture of water and ethylene glycol, a sleeve with a perforated bottom. A copper rod is located in the electrode body, and a potential sensor with a removable nozzle and at least two ion-exchange membranes are mounted on the body.

 In contrast to the prototype, the potential sensor of the claimed electrode has a removable nozzle installed depending on the thickness of the insulation layer in an underground metal structure. At least two ion-exchange membranes are mounted on the electrode housing, and the bottom of the coupling connected to the housing has perforations.

 The presence in the inventive electrode of a removable nozzle of the sensor, affecting the density of the cathode current of the sensor, provides improved measurement accuracy at different thicknesses of the insulating coating. The fact that two ion-exchange membranes are mounted in the claimed electrode increases the service life and stability of the electrode due to the prevention of a decrease in the concentration of copper sulfate in the electrolyte solution and a corresponding change in the electrode potential, the penetration of the electrolyte into the soil.

 The bottom of the coupling mounted on the housing protects the membrane from mechanical damage during installation and operation of the electrode, which increases the service life of the proposed electrode. Perforations in the bottom of the coupling allow electrolytic contact of the reference electrode with the electrolyte of the soil. The service life of the proposed reference electrode increases by an average of not less than 2–3 times in comparison with the manufactured electrodes due to a decrease in the osmotic transfer of moisture into the housing of the reference electrode after penetration of moisture into the intermembrane gap, leading to a drop in the osmotic pressure on the outer membrane, as well as the performance of the reference electrode in case of damage to the outer membrane. The accuracy of the potential measurement is increased due to the prevention of a decrease in the concentration of copper sulfate in the electrolyte solution and, as a result, a change in the electrode potential. The measurement accuracy is also improved by modeling the thickness of the insulation coating layer in the defect using a nozzle mounted on the sensor.

 The drawing shows a General view of the proposed reference electrode.

 It contains a copper rod 3, a housing 1 made of a dielectric material, such as plastic, an electrolyte 4, a sleeve with a perforated bottom 2, an internal ion-exchange membrane 5, an external ion-exchange membrane 6. The membranes 5 and 6 are pressed against the housing 1 through a seal 7 using a sleeve 2. The copper rod 3 is pressed into the housing 1 and closed by a cap 12. To connect the reference electrode and the potential sensor 8 to the measuring circuits, conductors 10 and 11 are used. The potential sensor 8 is equipped with a removable nozzle 9 made of plastic, the thickness of which th equivalent to the thickness of the anti-corrosion coating on an underground metal structure. The electrode body is filled with an electrolyte, which includes the following components: distilled water, copper sulfate (sulfate), ethylene glycol.

 The volume ratio of water to ethylene glycol is selected from 3: 2 to 2: 1. The copper sulfate content should ensure saturation of the solution with the release of free crystals of copper sulfate. The potential difference between the proposed reference electrode and a saturated silver-silver reference electrode is 120 ± 30 mV.

 Example 1. Two electrodes are assembled. Strengthen the ion exchange membrane at the bottom of the housing. An electrolyte of the composition is poured into the casing: 750 ml / l of water and 450 ml / l of ethylene glycol, in which copper sulfate is dissolved at a rate of 250 g / l to obtain a saturated solution with free crystals of copper sulfate. A homogeneous membrane with a thickness of 30 μm was used on the basis of a biaxially oriented polypropylene film with a radiation content of grafted methacrylic acid of 150%.

 The reference electrodes are placed in a vessel with distilled water and within six months they measure the potential of the reference electrode relative to the silver chloride reference electrode and the electrical resistance between the test electrodes. After the first month of testing, there was a tendency to a decrease in the potential difference between the test reference electrode and the silver chloride reference electrode. By the end of the tests (after 6 months), the potential difference of the reference electrodes was 102 and 96 mV (at the beginning of the tests, 123 and 119 mV, respectively). The color of the water in which the reference electrodes were located has changed, which indicates the release of part of the solution from the housing into the water.

 The membranes of the reference electrodes became convex and were pressed to the grids. The electrical resistance of the electrodes was 50-58 kOhm.

 Example 2. Collect electrodes of comparison as in example 1, but with two similar membranes. By the end of the tests, the potential difference between the reference electrodes was 119 and 118 mV (at the beginning of the tests, 121 and 123 mV, respectively), which indicates the absence of a noticeable tendency to lower electrode potentials and corresponds to the required measurement accuracy. The color of the water in which the reference electrodes were located remained virtually unchanged. The membranes of the reference electrodes did not become convex. The electrical resistance of the reference electrodes was 88-112 kOhm.

 Example 3. Collect electrodes as in example 1, but with three similar ion-exchange membranes. By the end of the tests, the potential difference of the reference electrodes was 123 and 121 mV (at the beginning of the tests, respectively, 122 and 125 mV), which indicates the absence of a noticeable tendency to decrease the potential of the reference electrodes. The color of the water in which the reference electrodes were located remained virtually unchanged. The membranes of the reference electrodes did not become convex. The electrical resistance of the reference electrodes was 137-144 kΩ.

Claims (2)

 1. The reference electrode is non-polarizable, containing a non-conductive housing with a sleeve, filled with an electrolyte from a saturated solution of copper sulfate in a mixture of water and ethylene glycol, a copper rod located in the housing, an ion-exchange membrane, a potential sensor mounted on the housing, characterized in that the potential sensor is equipped with a removable nozzle, at least two ion-exchange membranes are mounted on the electrode housing, and the bottom of the coupling mounted on the housing has perforations.  2. The electrode according to claim 1, characterized in that the removable nozzle is installed depending on the thickness of the insulation layer on the underground metal structure.