RU2483298C1 - Solid-electrolyte sensor for amperometric measurement of hydrogen and oxygen concentration in gas mixtures - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: solid electrolyte sensor for amperometric measurement of hydrogen and oxygen concentration in gas mixtures comprises a disc from solid electrolyte with oxygen conductivity, two electrodes applied onto opposite surfaces of this disc, a disc from a proton-conducting solid electrolyte with two electrodes applied on its opposite surfaces, and a capillary, both discs and the capillary are tightly connected to each other, and between the discs the sensor has an inner cavity.

EFFECT: possibility of simultaneous measurement of hydrogen and oxygen concentration in a gas mixture, simplified design of a sensor and its increased efficiency.

3 cl, 1 dwg

Description

The invention relates to an analytical technique, in particular to solid electrolyte sensors for analyzing gaseous media, and can be used to measure the concentration of both hydrogen and oxygen in gas mixtures of various compositions.

Known electrochemical potentiometric solid electrolyte sensor for measuring the concentration of hydrogen in gas and liquid media (patent RU 2120624, publ. 20.10.1998) [1]. In the body of the known sensor, a ceramic electrical insulator is installed, closed at the bottom with a plug of solid electrolyte, down conductors, reference and platinum electrodes. On the side of the plug of solid electrolyte, a tablet of porous insulating ceramic and a corrugated selective membrane are sequentially installed in the housing. The ceramic insulator is made on the basis of corrosion-resistant water vapor and hydrogen-impervious ceramics from a mixture of oxides BeO (52-70% wt.), MgO (30-45% wt.), CaO (0.005-3% wt.) And cork from single crystal stabilized with ZrO ₂ or HfO ₂ . The sensor is heated to an operating temperature (500 ° C and above) due to the heating element.

As a basis, the known sensor contains a solid electrolyte with oxygen-ionic conductivity, therefore, the measurement of the concentration of hydrogen in gas mixtures with this sensor can only be done indirectly, and oxygen is impossible.

Known diffusion amperometric sensor for measuring oxygen using solid electrolytes with oxygen-ion conductivity based on zirconium oxide with the addition of calcium or yttrium oxides (RU 55143, publ. 06.07.2005) [2]. The sensor contains a test tube made of a solid electrolyte with oxygen-ion conductivity, with porous platinum electrodes deposited on the inner and outer surfaces of the test tube, and a capillary, which serves as diffusion resistance, tightly attached to the test tube. As the analyzed gas, a gas mixture of oxygen-nitrogen or oxygen-argon is used. The operating temperature of the sensor is constant at 750 ° C. In the operating mode, under the action of a voltage applied from an external power source to the electrodes of the cell, oxygen is extracted from the cathode chamber and transferred through the solid electrolyte layer to the environment, and argon or nitrogen accumulates in the cathode chamber. Over time, a stationary state is established when the diffusion stream of nitrogen (argon) from the cathode chamber of the cell becomes equal to the stream of nitrogen (argon) entering the cathode chamber. In this case, the flow of oxygen through the diffusion barrier into the cathode chamber has a constant value.

The scope of the known sensor is limited to nitrogen-oxygen and inert gas-oxygen mixtures, because The sensor is only capable of measuring oxygen concentration. The low speed of the known sensor due to the significant volume of the tube. The sensor has large dimensions.

Known electrochemical sensor for measuring oxygen concentration, containing a disk of a solid electrolyte based on ZrO ₂ , stabilized Y ₂ O ₃ having oxygen-ion conductivity, and two electrodes deposited on opposite surfaces of the disk (US No. 4,547,281, publ. 15.10.1985 g .) [3]. The electrodes are made of LaCrO ₃ composition with graphite additives. During calcination, graphite burns out and creates a large number of pores in the volume of electrodes, which serve as cavities, from which oxygen is evacuated using a voltage source. The magnitude of the limiting current and determine the amount of oxygen in the analyzed volume. By dosing graphite into the electrode mass, the porosity of one electrode relative to the other is changed and the characteristics (speed, limit current) of the sensor are thus controlled. By means of a known sensor, it is possible to measure only the oxygen concentration, moreover, the technology for preparing electrodes with a given porosity is complex.

A solid electrolyte sensor for amperometric measurement of the concentration of hydrogen and oxygen in gas mixtures is declared, which, like the sensor [3], contains a disk of a solid electrolyte with oxygen conductivity, two electrodes deposited on opposite surfaces of this disk. The sensor is characterized in that it further comprises a proton-conducting solid electrolyte disk with two electrodes deposited on its opposite surfaces, and a capillary, while both disks and the capillary are hermetically connected to each other, and the sensor has an internal cavity between the disks. As a proton-conducting solid electrolyte, the sensor contains calcium zirconate, and the electrodes are made of porous non-catalytic material.

The essence of the claimed invention is as follows. The composition of the oxygen-conducting and proton-conducting solid electrolytes is selected from the maximum ionic conductivity of these materials for operation at a temperature of 500-600 ° C. Under the action of the voltage supplied to the electrodes of the oxygen-conducting disk, oxygen will be pumped out from the internal cavity of the sensor into the analyzed gas. At the same time, through the capillary, the analyzed gas will continuously flow from the environment into the internal cavity of the sensor and displace gas that is already depleted of oxygen from there. A stationary state will be established when the diffusion flow of the analyzed gas depleted in oxygen from the internal volume of the sensor becomes equal to the flow of the analyzed gas entering the internal chamber of the sensor. In the process of achieving a stationary state, the current flowing through the oxygen-conducting disk will reach a constant value, called the limiting diffusion current of the oxygen channel of the sensor - I ^kit. cm Similar processes will go on the proton-conducting disk. Under the influence of a voltage applied to its electrodes, hydrogen will be pumped out of the internal cavity of the sensor. Over time, a stationary state will be established when the diffusion flow of the analyzed gas depleted in hydrogen from the internal volume of the sensor becomes equal to the flow of the analyzed gas entering the inside of the sensor from the outside. The current flowing through the proton-conducting disk reaches a constant value, called the limiting diffusion current of the sensor’s hydrogen channel — I ^water. cm Thus, in the measurement mode from the sensor cavity through separate channels, but in a similar way, both oxygen and hydrogen can be continuously pumped out.

The fact that the use of electrodes made of porous materials increases the rate of gas diffusion through the layer of electrode material to the surface of the solid electrolyte and that two gases are simultaneously pumped out of the internal cavity of the sensor helps to increase the speed of the sensor. The use of electrodes made of non-catalytic materials reduces the likelihood of the interaction of hydrogen and oxygen on the surface of the electrodes with the formation of water, which increases the accuracy of the analysis.

A new technical result achieved by the claimed invention is the ability to simultaneously measure the concentration of hydrogen and oxygen in the gas mixture, as well as to simplify the design of the sensor and increase its speed.

The proposed solid electrolyte sensor contains a disk 1 of an oxygen-conducting solid electrolyte based on ZrO ₂ stabilized with Y ₂ O ₃ . On the opposite surfaces of this disk are applied internal 2 and external 3 porous electrodes made of non-catalytic material - Ag. Porous electrodes can be made, for example, of In ₂ O ₃ . The sensor contains a second disk 4 of proton-conducting solid electrolyte - calcium zirconate. The disk 4 can be made of other oxide compositions providing a transfer number due to hydrogen ions equal to or close to 1. On the opposite surfaces of the disk 4 are applied internal 5 and external 6 porous electrodes of non-catalytic material. These electrodes can be made of other oxide compositions providing a transport number due to oxygen ions equal to or close to 1. The sensor has a cavity 7, which can be organized due to the fact that the inner surface of one or both disks is made with a recess. Capillary 8 serves as a diffusion barrier and is washed by the flow of the analyzed gas. Both disks and the capillary are interconnected by glass - sealant 9. The sensor is in a uniform temperature field, which is created by the analyzed gas medium or heater.

In the measurement mode, under the action of a voltage applied from an external IN-1 power source to the electrodes of disk 1 (plus a source to the external electrode), oxygen is pumped from the internal cavity of the sensor into the analyzed gas. To exclude the electrolysis of water vapor, the applied voltage from the IN-1 source should be less than 1 V. The analyzed gas through the capillary continuously enters from the environment into the internal cavity of the sensor and displaces the gas already depleted of oxygen from there. Over a short period of time, a stationary state is established when the diffusion flow of the analyzed gas depleted in oxygen from the internal volume of the sensor becomes equal to the flow of the analyzed gas entering the internal chamber of the sensor. The current flowing through the disk from an oxygen-conducting solid electrolyte in the process of reaching a stationary state changes, reaching a constant value when the stationary state is established, called the limiting diffusion current of the oxygen channel of the sensor — I ^kit. cm The value of the diffusion current of the oxygen channel is measured by an IT-1 current meter. Similar processes occur on the proton-conducting disk 4. Under the influence of the voltage applied to the electrodes of the disk 4 (minus the source - to the external electrode), hydrogen is pumped out of the internal cavity of the sensor. After a short period of time, a stationary state is established when the diffusion flow of the analyzed gas depleted in hydrogen from the internal volume of the sensor becomes equal to the flow of the analyzed gas entering the internal chamber of the sensor from the outside. The current from the IN-2 external source, flowing through the disk from the proton-conducting solid electrolyte in the process of reaching a stationary state, changes, reaching a constant value when the stationary state is established, called the limiting diffusion current of the sensor’s hydrogen channel — I ^water. cm The diffusion current of the hydrogen channel is measured by an IT-2 current meter. In general terms, both for the oxygen and hydrogen channels of the proposed sensor, the volume fraction of oxygen and hydrogen in the analyzed gas is related to the limiting diffusion current I ^cis. cm and I ^water. cm., respectively, by the ratio / 3 /:

where C is the volume fraction of the analyzed component in the analyzed gas,%;

Icm. - limit current of the corresponding channel, A;

K is a coefficient depending on the length of the capillary and the diameter of its inner channel, on operating conditions and the diffusion coefficient.

Thus, by measuring the magnitude of the limiting currents for oxygen and hydrogen I ^kis. cm and I ^water. cm, characteristic of given concentrations of hydrogen and oxygen, according to equation (1), we can uniquely determine the concentrations of each of these gases in the analyzed medium. At the same time, the claimed sensor has a simplified design and has a speed.

Claims (3)

1. A solid electrolyte sensor for amperometric measurement of the concentration of hydrogen and oxygen in gas mixtures, containing a disk of a solid electrolyte with oxygen conductivity, two electrodes deposited on opposite surfaces of this disk, characterized in that the sensor further comprises a disk of proton-conducting solid electrolyte with two electrodes, deposited on its opposite surfaces, and the capillary, while both disks and the capillary are tightly interconnected, and between the disks the sensor has an internal olost. 2. The sensor according to claim 1, characterized in that as a proton-conducting solid electrolyte contains calcium zirconate. 3. The sensor according to claim 1, characterized in that the electrodes are made of porous non-catalytic material.