JPH02201257A - Oxygen sensor - Google Patents

Abstract

PURPOSE:To enable a larger size of a sensor with easy formation of a protective construction by covering a sensor body, a plate body and a conductor layer integral with a porous material to form the protective construction. CONSTITUTION:A sensor body 10 is made up of an ion conducting plate 11 made thin of a solid electrolyte, porous electrodes 12A and 12B formed on both sides thereof and a seal cap 13 covering a lower side of the ion conducting plate 11. A heater 14 is provided further below the ion conducting plate 11. The seal cap 13 is made up of a porous sintered body 15 made of an alumina powder or the like provided to cover one of the electrodes entirely and a glass layer 16 covering the porous sintered body 15 entirely. The sensor body 10, the heater 14 and the end of the plate body 17 are covered with a porous material 21 is package. After the sensor 10 is immersed into a bath of a ceramic based adhesive, the porous body 21 is formed by drying or the like on specified conditions.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an oxygen sensor used for preventing oxygen deficiency accidents in underground tunnels, and particularly to a small and inexpensive oxygen sensor.

[Conventional technology] In recent years, solid electrolytes made of stabilized zirconia have been developed.

As shown in FIG. 7, this oxygen sensor consists of an ion conductive plate l formed with a thickness thinner than that of a solid electrolyte having ionic conductivity such as stabilized zirconia, and an ion conductive plate l provided on both sides of the ionic conductive plate l. A sealing cap 3 is provided to cover one surface of the ion conductive plate 1, and has porous electrodes 2A and 2B to which a predetermined voltage is applied, and a diffusion hole 3A that causes diffusion rate limiting in the center. and a heater 4 provided on the upper surface of the sealing cap 3 to apply heat to the ion conductive plate l.
As shown in the figure, it is assembled into a unit consisting of a stem 6, electrode vials 7.8, a porous drip-proof membrane 9, and the like.

Now, arrange the oxygen sensor shown in FIG. 6 so that the sensor body 5 is exposed to the atmosphere in which you want to measure the oxygen concentration, and connect the electrode via the electrode bottle 7.8 to a drive circuit (not shown). If voltage is applied to 2A, 2B and the heater 4, the electrode 2A.

The oxygen concentration in the atmosphere can be determined from the value of the current flowing between 2B.

[Problems to be Solved by the Invention] Incidentally, the oxygen sensor configured as described above has the following problems that should be improved.

That is, usually the electrodes 2A, 2B or the heater 4,
Since the connection with the electrode pin is made by a fine lead wire, the lead wire is easily broken due to vibration, etc., and there is a problem that the reliability of the connection is low.

Furthermore, the sensor body 5 is normally attached to the stem 6 etc. by supporting it with fine ceramic fibers, but this work is difficult, and it is also difficult to attach the drip-proof membrane 9 to assemble it as a unit. Since it is difficult and requires a lot of man-hours, the cost of the oxygen sensor is high.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an oxygen sensor that is compact and easy to manufacture, including a protective structure for the sensor body, and has enhanced protection for the sensor body. [Means for Solving the Problems] The oxygen sensor of the present invention is made of an ion conductive plate formed from a solid electrolyte into a plate shape and provided with electrodes on both sides, and a sealing cap is placed on one side of the ion conductive plate. A main body is attached to one end of an insulating plate, and a conductive layer is formed on the surface of the plate, connected to the electrode of the sensor body and extending to the other end of the plate, and The sensor body, the plate body, and the conductor layer are all covered with a porous material.

[Function] The oxygen sensor of the present invention forms a protective structure for the sensor body and the like by collectively covering the sensor body, the plate, and the conductor layer with a porous material. Therefore, the protective structure can be easily formed using conventional molding techniques, and the protective structure does not increase the size of the oxygen sensor as a whole.

[Example] Hereinafter, an example of the present invention will be described with reference to FIGS. 1 to 5.

Fig. 1 is a plan view of the oxygen sensor, Fig. 2 is a side sectional view, and Fig. 3 is a plan view of the oxygen sensor.
The figure is a rear view (however, FIGS. 1 and 3 show the state before being coated with a porous body, which will be described later).

In the figure, what is indicated by the symbol IO is the sensor body, which is made of stabilized zirconia (for example, ZrO□-8Y20i).
An ion conductive plate 11 formed of a thin solid electrolyte having ionic conductivity such as
A predetermined voltage (for example, about 2 volts) is formed on both sides of the
It is composed of porous electrodes 12A, 12B to which ion conductive plate 11 is applied, and a sealing cap 13 that covers the lower side (lower side in FIG. 2) of the ion conductive plate 11.

Furthermore, a heater 14, which will be described later, is provided further below the ion conductive plate 11 to apply heat to the ion conductive plate 11.

The sealing cap 13 includes a porous fired body 15 such as alumina powder provided to completely cover the electrode 12A on one side, and a glass layer provided to completely cover the porous fired body 15. It is composed of 16.

Further, a gas diffusion hole 11A is formed in the ion conductive plate 11 and extends vertically into the sealing cap 13, and the gas diffusion hole 11A restricts the intake of outside air to create diffusion rate limiting. It has become.

Inside the ion conductive plate 11 as described above, between the electrodes 12A and 12B, an ion current using oxygen ions in the outside air taken in through the gas diffusion holes 11A as carriers flows due to the oxygen pumping action, and these ions The oxygen concentration in the atmosphere can be determined from the current saturation value (limiting current).

Next, both the sensor main body 10 and the heater 14 described above are
A mounting structure for mounting on a plate indicated by reference numeral 17 will be explained.

The base of the plate body 17 is formed of a material having an expansion coefficient similar to that of the ion conductive plate 11, such as Zr02-3y, o, etc., and the surface thereof is sintered and coated with alumina powder or crystallized glass. The sealing cap 13 side of the sensor body 1O is attached to one end of the upper surface 17A by adhesive, and the one end of the lower surface 17B thereof is The heater 1 is located below the main body 1O.
4 is provided by printing, plating, etc.

An adhesive layer 18 is formed between the sensor body 1O and the upper surface 17A of the plate 17 using a ceramic adhesive containing alkali ions or by mixing glass with alumina powder and firing the mixture. The adhesive layer 18 is formed to have a porous structure, and this structure prevents distortion caused by the difference in thermal expansion coefficient between the sensor body lO and the plate body 17. It is now possible to relax.

On the other hand, on the upper surface 17A of the plate 17, a conductor layer 19A, which is connected to the electrodes 12A and 12B of the sensor body 10, respectively.
19B, and a heater 14 on the lower surface 17B of the plate body 17.
The conductor layer 20A is connected to the conductor layer 20A.

20B is formed.

These conductive layers 19A, 19B, 20A, 20B are formed by wire bonding or conductive paste, and are formed from one end of the plate 17 to which the sensor body 1O or the heater 14 is attached, They are arranged in a band shape towards the end.

Then, the sensor body 10. The heater 14 and the end portions of the plate body 17 to which they are attached are collectively covered with a porous body 21 . This porous body 21 is formed porous by coating it with, for example, a ceramic adhesive and firing or drying it at a relatively low temperature.

Here, as a specific method for coating this porous body 21, for example, after immersing the sensor body lO etc. in a bath of ceramic adhesive, predetermined conditions (for example,
For example, drying at around 11° C. for about 30 minutes can be used.

Next, the drive circuit for the oxygen sensor configured as described above will be explained with reference to the block diagram shown in FIG. 4.

In the figure, what is indicated by the reference numeral 100 is an oxygen sensor, and this oxygen sensor 100 includes the conductor layer 19A,
Terminal 10 connected to 19B, 20A, 20B respectively
2A, 102B, l0IA.

101B are provided respectively.

The terminals 101A and 101B are connected to a heater voltage application circuit 103 for causing the heater 14 to generate heat, and this heater voltage application circuit 103 changes the voltage applied to the heater 14 by adjusting a variable resistance. It is now possible to do so.

The terminal 102A is connected to a sensor monitoring voltage application circuit 104 for applying a predetermined voltage to the electrodes 12A and 12B.
In this case, the sensor voltage of the sensor body 10 can be changed by adjusting the variable resistor.

The terminal 102B is used to sequentially connect an IV conversion circuit 105 and an amplifier circuit 106, and converts the limiting current value of the ion conductive plate 11 into a voltage value in the 1-V conversion circuit 105. output, and furthermore, the amplification circuit 108
, the voltage value output from the previous Ex-v conversion circuit 105 is amplified, and the amplified signal is used as a detection signal at the terminal 10.
I am trying to output from 7.

Note that in the 1-V conversion circuit 105 and the amplifier circuit 106, it is possible to change the output voltage level or amplification degree by adjusting the variable resistors.

Then, by the drive circuit as described above, the sensor voltage is applied to the electrode 12A112B, and the heater voltage is applied to the heater 1.
4, oxygen gas and ionized oxygen flow as shown by the arrows in FIG. Voltage is output from terminal 107.

Here, the connection of the oxygen sensor to the drive circuit is as follows:
The ends of the conductor layers 19A, 19B, 20A, 20B of No. 7 are used as electrodes to connect the terminals 101A, 10
This can be done simply and reliably by fitting into a connector provided with IB, 102A, 102B.

As explained above, according to the oxygen sensor configured as above, the sensor body 1G, the heater 14, and the plate to which they are attached! The end portion of 7 is covered with a porous body 21 . Therefore, external pressure fluctuations and the like are less likely to affect the sensor body 1O and the heater 14, and the output does not become unstable due to wind or the like. In addition, since it is difficult for water etc. to enter the inside, problems caused by water droplets etc. adhering to the sensor main body 1O and the heater 14 can be prevented.

The protective structure using the porous body 21 can be easily formed using conventional molding techniques. In addition, the conductor layer 19A
, 19B, 2OA, and 20B can be formed by printing, so they are much easier to manufacture than conventional configurations consisting of drip-proof membranes, lead wires, etc., and are suitable for mass production and have the advantage of being low cost. be.

Further, since protection from water droplets and the like is provided by the coating with the porous body 21 as described above, the protective structure does not increase the size of the entire oxygen sensor compared to a conventional drip-proof film.

Therefore, the oxygen sensor as a whole unit can be made extremely compact.

The porous body 21 also has the function of supporting the sensor body 10 or the conductor layer connected thereto, further increasing the reliability of the connection and increasing the vibration and shock resistance of the entire oxygen sensor. .

Furthermore, in the oxygen sensor of this embodiment, the coating of the porous body 21 has a relatively low temperature under the temperature conditions (approximately 800° C. or higher) such as baking performed when forming the electrodes 12A, 12B, the glass layer 16, etc. Since the formation of the porous body 21 is carried out under temperature conditions, the electrode 12A is removed.

12B, the glass layer 16, and the like are not affected by deterioration or deformation.

In addition, in the above embodiment, the sealing cap 1 of the sensor body lO
Although the third side is attached to the plate 17, the present invention is not limited to this structure. For example, the ion conductive plate 11 side may be attached to the plate 17 as shown in FIG.

[Effects of the Invention] In the oxygen sensor of the present invention, the end portion of the plate to which the sensor body is attached is entirely covered with a porous material.

For this reason, external pressure fluctuations, etc. are difficult to reach the sensor body.
The output will not become unstable due to wind, etc. In addition, since it is difficult for water etc. to enter the sensor body, problems caused by water droplets etc. adhering to the sensor body can be prevented.

The protective structure made of this porous material can be easily formed using conventional molding techniques. In addition, since the conductor layer can be easily formed by printing, it is much easier to manufacture than conventional structures consisting of drip-proof films, lead wires, etc., and is suitable for mass production and has the effect of reducing costs. be.

In addition, protection from water droplets and the like is provided by the porous coating as mentioned above, so compared to conventional drip-proof membranes, the protection is much better.
The 111I construction prevents the entire oxygen sensor from becoming larger. For this reason, there is an effect that the oxygen sensor as a whole can be made extremely compact.

[Brief explanation of the drawing]

1 to 5 are views showing embodiments of the present invention, in which FIG. 1 is a plan view of an oxygen sensor, FIGS. 2 and 5 are side sectional views of the oxygen sensor, and FIG. 3 is a side sectional view of the oxygen sensor. Rear view of oxygen sensor,
FIG. 4 is a block diagram of the drive circuit. Moreover, FIG. 6 and FIG. 7 are diagrams showing the conventional technology,
FIG. 6 is a diagram showing the entire oxygen sensor, and FIG. 7 is a diagram showing the sensor body. 11... Ion conductive plate, 12A, 12B... Electrode, 13... Sealing cap, 17... Plate body, 19A, 19B...・Conductor layer, 21...
・Porous body.

Claims (1)

[Claims] A sensor body is attached to one end of the insulating plate body, which is formed by covering one side of an ion conductive plate formed of a solid electrolyte in a plate shape and provided with electrodes on both sides with a sealing cap. A conductive layer connected to the electrode of the sensor body and extending to the other end of the plate is formed on the surface of the plate, and the sensor body, the plate, and the conductor layer are collectively made of a porous material. An oxygen sensor characterized by being coated.