JPH0448530Y2 - - Google Patents

Description

[Detailed Description of the Invention] "Industrial Application Field" The present invention relates to an oxygen sensor for measuring oxygen concentration in a gas to be measured.

“Prior Art” Conventionally, as an oxygen sensor for measuring oxygen concentration (oxygen partial pressure) in a gas to be measured, for example,
A device using a sensor element having the structure shown in FIG. 2 or FIG. 2 is known.

_The sensor element 1 _{shown in} FIG.
A thin film electrode 3 made of platinum or the like is provided on both sides of a capsule 4 which covers one of these electrodes 3. The structure is such that an oxygen diffusion control body 6 consisting of a minute diameter diffusion hole 5 is provided. In addition, the sensor element 7 shown in FIG. 2 has an oxygen diffusion control body 8 formed of a porous body having a large number of continuous pores in place of the oxygen diffusion control body 6 of the sensor element 1 shown in FIG. It has a configuration with .

The sensor elements 1 and 7 configured in this manner are connected between the two electrodes 3 by a DC power source A in a direction from the outside to the inside of the sensor elements 1 and 7 (in the direction of arrow A in FIG. 1). The oxygen concentration in the gas to be measured G is measured by using a so-called pumping action, which is a so-called pumping action that forces a current to flow and releases the oxygen in the sensor elements 1 and 7 to the outside via the oxygen ion conductive plate 2. It's getting old.

That is, during the aforementioned pumping action,
External oxygen is diffused into the sensor elements 1, 7 through the diffusion holes 5 (continuous pores) of the oxygen diffusion controllers 6, 8, but the amount of oxygen released by the pumping action is greater than the amount of this oxygen diffused. When the current value is set to increase, the voltage generated between the two electrodes 3 exhibits a change characteristic divided into the following three regions, as shown by a voltage change curve a in FIG.

(X): Transient region from when current is applied until the pumping action reaches a steady state.

(P): Pumping region where pumping action is performed in a steady state (in this region, a stable pumping voltage Vp is obtained).

(Z): Rate-determining region where the oxygen in the sensor elements 1 and 7 is in a dilute state and the amount of oxygen released from the oxygen ion conductive plate 2 is almost 0 (in this region, the internal resistance of the oxygen ion conductive plate 2 increases) (and the voltage increases rapidly).

and the duration of said pumping region (P);
That is, the pumping time dt is obtained corresponding to the oxygen concentration in the gas G to be measured.

Therefore, the magnitude of the current and the various shapes and dimensions of the sensor elements 1 and 7 (for example, the diameter and length of the diffusion hole 5 in the case of the sensor element 1, and the oxygen diffusion control in the case of the sensor element 7) porosity of the body 8) is kept constant, and the pumping time dt
By detecting the above-mentioned sensor element 1,
Measurement of oxygen concentration is performed according to No. 7.

As shown in FIG. 4, the above-mentioned sensor elements 1 and 7 include an electrode post 10 provided on a flat stem 9 and penetrating through this stem 9, and between this electrode post 10 and the electrode post 10. The oxygen sensor is supported by an electrode lead wire 11 connected between the oxygen sensor and the oxygen sensor. on the other hand,
The reference numeral 12 in the figure is a cover formed of metal mesh. However, in such a conventional oxygen sensor, fine dust and the like in the measurement area enter the interior through the mesh of the cover 12, and the oxygen which is a part that has an important influence on the characteristics of the sensor elements 1 and 7 is removed. It may block the diffusion pores 5 (continuous pores) of the diffusion control bodies 6 and 8 or adhere to the surface of the electrode 3, reducing the three-phase interface and reducing the measurement accuracy of the oxygen sensor. There is. Furthermore, since the sensor elements 1 and 7 are supported by the electrode lead wires 11,
The support of sensor elements 1 and 7 tends to become unstable,
When the non-measured gas G forms a flow around the sensor elements 1 and 7, heat retention is likely to be reduced, and from this point of view as well, there is a risk that the measurement accuracy of the oxygen sensor may be reduced.

``Purpose of the invention'' The present invention was made in view of the conventional circumstances mentioned above, and aims to prevent clogging of the oxygen diffusion control body of the sensor element, improve heat retention, and prevent deterioration of measurement accuracy. An object of the present invention is to provide an oxygen sensor that can reliably support a sensor element.

"Structure of the Invention" In order to achieve the above-mentioned object, the present invention includes a sensor element for detecting the oxygen concentration in a gas to be measured, a stem having a recess for attaching the sensor element,
The sensor element includes an oxygen ion conductive plate formed of a solid electrolyte and an oxygen ion conductive plate integrally formed with the oxygen ion conductive plate. It consists of two electrodes provided and an oxygen diffusion control body fixed to an oxygen ion conductive plate covering one of these electrodes, and an opening for oxygen diffusion is formed in the recess. Features.

"Embodiment" The present invention will be described in detail below based on an embodiment shown in FIGS. 5 and 6. In the following description, the same reference numerals are used for parts common to those in FIGS. 1 to 4 to simplify the description.

As shown in FIGS. 5 and 6, the oxygen sensor according to this embodiment includes sensor elements 1 and 7 for detecting the oxygen concentration in the gas G to be measured, and a recess 31 for attaching the sensor elements 1 and 7. stem with 13
and the stem 1 covering the sensor elements 1 and 7.
The sensor elements 1 and 7 include an oxygen ion conductive plate 2 formed of a solid electrolyte, and a fibrous filler 14 filled between the oxygen ion conductive plate 2 and the oxygen ion conductive plate 2. two electrodes 3 provided;
3, and oxygen diffusion control bodies 6, 8 fixed to the oxygen ion conductive plate 2 covering one of these electrodes 3, 3.
A basic configuration in which an opening 32 for oxygen diffusion is formed at the center bottom of the recess 31, and the filler 14 is made of a material with low thermal conductivity and high heat resistance. It is becoming.

The stem 13 is made of a material with low thermal conductivity, and has a power supply terminal 1 on the side thereof for supplying drive current to the sensor elements 1 and 7.
5 and a heater terminal 16 for supplying heating current are integrally provided in a penetrating state.

In the sensor elements 1 and 7, a heater 17 made of a resistance heating element is integrally provided on the upper surface of the oxygen diffusion control bodies 6 and 8. This heater 17 is then connected to the heater terminal 1 via a heater lead wire 18.
6, and the electrodes 3 of the sensor elements 1 and 7 are connected to the power supply terminal 15 via the electrode lead wire 19, so that the stem 1
3 with a space between it and the inner wall surface thereof.

The filler 14 is made of, for example, ceramic fiber, glass fiber, or asbestos.
A cotton-like body of short fibers having heat resistance or a ceramic powder such as Al ₂ O ₃ having appropriate air permeability and particle size is filled between the sensor elements 1 and 7 and the stem 13. It is designed to maintain the distance between the two. In the sensor element 1, at least to prevent filler from entering the diffusion hole and changing the diffusion resistance value, for example, a protective member such as a metal mesh is placed over the opening of the diffusion hole 5 to prevent clogging. It is desirable to do so. Further, when the filler is a cotton-like material, if the cotton-like material is molded in advance so that some space is formed above the opening, a protective member may not be particularly required. The density of the filling material is set so that it has a sufficient dustproof effect even if the air permeability is somewhat impaired.

On the other hand, in FIGS. 5 and 6, reference numeral 20 is a cover formed of metal mesh;
As shown in the figure, it is fixed to the stem 13 so as to cover the opening 32 of the stem 13.

The oxygen sensor of this embodiment configured as described above is installed in the gas to be measured G, and then the heater 1 is
By supplying a heating current to sensor element 7 through heater terminal 16 and heater lead 18 to heat sensor elements 1 and 7 to operating temperature, the oxygen concentration can be measured.

From this state, a driving current is supplied between the electrodes 3 and 3 via the power supply terminal 15 and the electrode lead wire 19 to cause the sensor elements 1 and 7 to perform a pumping operation, thereby causing the gas to be measured G The oxygen concentration inside can be measured.

During such an oxygen concentration measurement operation, the sensor elements 1 and 7 are covered with the fibrous filler 14 over almost the entire circumference.
Because it is covered with The flow of G is suppressed to prevent the temperature of the sensor elements 1 and 7 from decreasing. Further, since the filler 14 is fibrous, the diffusion of oxygen in the gas G to be measured is not inhibited. Therefore, stable pumping operations of the sensor elements 1 and 7 can be maintained, and a decrease in oxygen concentration measurement accuracy can be prevented. Moreover, the sensor element 1,
The space between them is maintained by the fibrous filler 14 interposed between the stem 13 and the stem 13, and even if an external force is applied to the stem 13, the filler 14 acts as a so-called buffer material. As a result, the sensor elements 1 and 7 can be supported reliably, and damage to the sensor elements 1 and 7 can be avoided, especially at the connections between the lead wires 18 and 19 and the terminals 15 and 16, the electrodes 3, and the heater 17. Disconnection, etc. can be prevented. Therefore, durability can be significantly improved.

The shapes of the sensor elements 1, 7, stem 13, cover 20, and other constituent members shown in the above embodiments are merely examples, and can be modified in various ways. Further, although a fibrous filler was used as the filler in the above embodiments, a powder filler may also be used. Further, the inner surfaces of the cover 20 and the stem 13 may be plated with metal to reflect the radiant heat from the sensor elements 1 and 7 toward the sensor elements 1 and 7, thereby increasing the heat retention effect.

"Effects of the Invention" As explained above, the oxygen sensor according to the present invention provides the following excellent effects.

The fibrous or powder filler prevents dust, etc. in the gas to be measured from adhering to the oxygen diffusion control body, electrodes, etc., and prevents clogging of the oxygen control body and reduction of the three-phase interface. can.

The filler maintains the distance between the sensor element and the stem, prevents or alleviates external forces acting on the stem from being transmitted to the sensor element, and protects the sensor element and other components connected thereto. Damage can be prevented.

Due to the synergistic effect of the above-mentioned effects, it is possible to perform stable oxygen concentration measurements, and
Durability can be significantly improved.

[Brief explanation of the drawing]

In the drawings, FIGS. 1 and 2 are longitudinal cross-sectional views showing structural examples of a sensor element equipped with an oxygen ion conductive plate formed of a solid electrolyte, and FIG. 3 is a longitudinal sectional view of FIGS. 4 is a perspective view showing the structure of a conventional oxygen sensor using the sensor element shown in FIG. 1, and FIGS. 6 shows an embodiment of the present invention, FIG. 5 is a longitudinal sectional view, and FIG. 6 is a sectional view taken along the line - in FIG. 1, 7... Sensor element, 2... Oxygen ion conductive plate, 3... Electrode, 6, 8... Oxygen diffusion control body, 1
3...Stem, 14...Filling material, 15...Power supply terminal, 16...Heater terminal, 17...Heater, 1
8... Lead wire for heater, 19... Lead wire for electrode, 20... Cover, 31... Recess, 32... Opening.

Claims (1)

[Claims for Utility Model Registration] Sensor elements 1 and 7 for detecting the oxygen concentration in the gas to be measured G, and a recess 31 for mounting the sensor elements.
a dustproof filler 14 filled between the stem 13 and the stem and covering the sensor element.
The sensor element includes an oxygen ion conductive plate 2 formed of a solid electrolyte, two electrodes 3 integrally provided on the oxygen ion conductive plate, and an electrode that covers one of these electrodes. An oxygen sensor comprising oxygen diffusion control bodies 6 and 8 fixed to an oxygen ion conductive plate, and characterized in that an opening 32 for oxygen diffusion is formed in the recess.