JPH0535325Y2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to an oxygen sensor for detecting the oxygen concentration in a gas to be measured, particularly in exhaust gas discharged from an internal combustion engine, and in particular, the present invention relates to an oxygen sensor for detecting the oxygen concentration in a gas to be measured, particularly in exhaust gas discharged from an internal combustion engine. This invention relates to an oxygen sensor with a heater that is heated by a heater that is inserted and arranged inside the cylinder.

Conventionally, the oxygen concentration of exhaust gas, which is the gas to be measured emitted from internal combustion engines such as automobiles, has been detected using the oxygen ion conductive solid electrolyte such as zirconia and the principle of oxygen concentration batteries. It is known to control the air-fuel ratio. This type of oxygen sensor, which is an oxygen concentration detector, has a cylindrical zirconia solid electrolyte with a bottom, and a predetermined electrode, such as a porous platinum electrode, is provided on the inner and outer surfaces of the zirconia solid electrolyte, and the electrode on the inner surface of the cylinder is brought into contact with the atmosphere. In this way, the electrode is used as the reference oxygen concentration electrode, while the electrode on the outer surface of the cylinder is exposed to the exhaust gas, which is the gas to be measured, to serve as the measurement electrode. The oxygen concentration in the exhaust gas is measured by detecting an electromotive force based on the difference in oxygen concentration between the reference electrode and the measurement electrode.

In addition, the electromotive force in such a solid electrolyte is unstable unless the solid electrolyte is heated to a certain degree, so it is difficult to maintain an accurate air-fuel ratio during idling or immediately after starting when the exhaust gas of the internal combustion engine is at a low temperature. In order to solve this problem, a rod-shaped heater is inserted into the solid electrolyte cylinder to forcibly heat the solid electrolyte. Oxygen sensors with heaters are being considered.

By the way, in a conventional sensor with a heater of this kind, a center electrode lead for extracting an electromotive force signal of the solid electrolyte from an electrode provided on the solid electrolyte in the shape of a cylinder with a bottom is disposed inside the sensor. However, such a center electrode lead is also susceptible to movement due to vibrations during sensor assembly work or during use, relative to the heater lead for passing current to the heater disposed within the sensor. Therefore, there was a problem that they easily came into contact with each other, causing a short circuit there.

The present invention was developed in view of the above circumstances, and its purpose is to position the heater and center electrode disposed within the sensor, and to connect the heater lead and the center electrode lead. An object of the present invention is to provide an oxygen sensor that effectively prevents short circuits.

In order to achieve this purpose, the present invention uses a bottomed cylindrical solid electrolyte with predetermined electrodes provided on its inner and outer surfaces, and a closed end of the fixed electrolyte that is exposed to the gas to be measured. a housing that hermetically isolates the inside of the cylinder into which the atmosphere is introduced from the gas to be measured; a rod-shaped heater that is inserted into the solid electrolyte cylinder and heats the solid electrolyte; In an oxygen sensor having an annular center electrode lead for extracting an electromotive force signal of the solid electrolyte, which is extrapolated and connected to the inner electrode, a ceramic sheet is provided with holes at predetermined positions as the heater. A part of the center electrode lead is placed in a recess formed by the hole on the outer surface of the heater using a heater having a heating element inside, which is obtained by winding a rod around a rod-shaped body and firing it. By fitting them together, the center electrode lead is positioned relative to the heater.

Hereinafter, in order to clarify the configuration of the present invention more specifically, embodiments of the present invention will be described in detail based on the drawings.

First, in FIG. 1, 2 is a bottomed cylindrical solid electrolyte made of zirconia or the like, and predetermined electrodes, for example, porous platinum electrodes (not shown) are provided on the inner and outer surfaces of the solid electrolyte, respectively. These electrodes allow the electromotive force of the solid electrolyte 2 to be detected, as is well known.

A metal housing 4 having a cylindrical shape is attached to the outer periphery of the solid electrolyte 2 on the open side via a contact packing 8, and is exposed to the outer surface of the closed end of the solid electrolyte 2. The solid electrolyte 2 is housed and held so that the inside of the cylinder of the solid electrolyte 2 is airtightly isolated from the gases to be measured. Specifically, in a state where the solid electrolyte 2 is inserted into the gas to be measured, the housing 4 is attached at its flange portion 6 to a passage member (not shown) such as an exhaust gas pipe through which exhaust gas passes. As a result, the inside of the cylinder of the solid electrolyte 2 is cut off from the gas to be measured.

Note that the solid electrolyte 2 for this housing 4
By housing the solid electrolyte 2, the outer electrode (measuring electrode) of the solid electrolyte 2 is connected to the housing 4 via the contact packing 8 interposed at the abutting part between them, and the The potential on the outside is taken out to the outside. The housing 4 also includes a solid electrolyte 2.
A protective cover 10 is provided to protect the outer surface of the flange 6 from the gas to be measured, and a gasket 12 is further provided to provide a seal between the passage member and the flange portion 6.

Further, the housing 4 has a cylindrical protrusion 14 that forms an opening on the atmosphere communication side at the end of the solid electrolyte 2 on the opening side, and the housing 4 has a cylindrical protrusion 14 that forms an opening on the atmosphere communication side. Various sensor members (components) are connected or arranged to protrude further outward from the protrusion 14 to constitute a sensor.

That is, a round rod-shaped heater 16 of a predetermined length is housed in the cylinder of the solid electrolyte 2, and the rear part of the heater 16 is arranged so as to protrude rearward from the cylindrical protrusion 14. There is.
Furthermore, two cylindrical insulators 18 and 20 that surround the rearward protruding portion of the heater 16 and form an insulating space are assembled via a spacer member 22, and the end of one of the insulators 18 The insulator 18 is fitted into the cylindrical protrusion 14 of the housing 4 so that the heater 16 is inserted through the cylindrical projection 14 of the housing 4.

Then, such sensor members (16, 18,
A cylindrical metal cap 24 is inserted so as to surround the outside of the metal housing 20, 22) and cover it with a predetermined space, and one end of the metal cap 24 is attached to the outer peripheral surface of the cylindrical protrusion 14 of the metal housing 4. It is crowned and fixed by caulking at several points in the circumferential direction. Further, the other end of the cap 24 is provided with a stepped small diameter portion, into which a rubber stopper 26 is attached to close the rear opening of the cap 24, which is the rear end of the sensor. The three lead wires 28a, 28b, 28c are
Each of them passes through the rubber stopper 26 and is led into the insulator 20 from the outside. Further, a disc spring 30 is disposed at the stepped portion on the small diameter side of the rear end of the cap 24, and the disc spring 30 presses the insulators 20, 18 against the housing 4. ing.

Further, the center electrode lead 32 having an annular shape is
It is inserted outside the heater 16, and the rear end surface of the solid electrolyte 2 and the insulator 1 are connected at the flange portion thereof.
A narrow pressure is maintained between the solid electrolyte 2 and the front end surface of the solid electrolyte 2, so that the conductive portion extending from the inner electrode (reference electrode) of the solid electrolyte 2 is brought into contact and connected to the inner electrode. ing. As clearly shown in FIG. 2a, this center electrode lead 32 has a plurality of holding pieces 34 extending rearward over a predetermined length in its circumferential direction. The holding piece 34 allows the center electrode lead 32 to be inserted against the heater 16 with a predetermined resistance. Furthermore, one of the holding pieces 34 of the center electrode lead 32 is provided with a protrusion 36 that protrudes inward.

On the other hand, a second
As can be seen in Figures a and b, a recess 38 is provided. The heater 1 is placed in this recess 38.
The protrusion 36 provided on one of the holding pieces 34 of the center electrode lead 32 which is fitted onto the center electrode lead 6 is fitted. By fitting a portion of the center electrode lead 32 into the recess 38 of the heater 16, the center electrode lead 32
is effectively positioned relative to the heater 16, and the center electrode lead 32 is rotated around the heater 16.
It can be effectively prevented.

Therefore, there is a risk that the signal lead 40, which is integrally provided on one of the holding pieces 34 of the center electrode lead 32, may come into contact with the heater lead 42, which is brazed and fixed to the conductive part of the rear end of the heater 16. , these leads 4 may be substantially eliminated due to vibrations during sensor assembly work or during use.
This eliminates the problem of short-circuiting between terminals 0 and 42, and therefore the assembly work becomes easier. Note that the signal lead 40 and the heater lead 42 are the lead wires 2 inserted through the rubber plug 26, respectively.
8a, 28b, and 28c are connected to each other by caulking via connectors 44, and are electrically connected.

Incidentally, the recess 38, which is thus provided at a predetermined position on the outer surface of the heater 16 and into which a part of the center electrode is fitted, can be advantageously formed in the configuration shown in FIG. .

That is, in the embodiment shown in FIG. 3, as shown in c of FIG. While a predetermined pattern consisting of 50 is formed,
Holes 52 are previously punched at predetermined locations on the sheet. Then, the unfired ceramic sheet 46 with such printing is wrapped around a predetermined rod-shaped body, for example, the ceramic rod 54, with the printed surface facing inside, and then fired. , an integrated heater 16.

In the heater 16 obtained in this way, the hole 52 portion provided in the ceramic sheet 46 becomes the recess 38 for positioning the desired center electrode lead 32, and as shown in FIG. As shown in FIG. 3B, the protrusion 36 of the holding piece 34 of the center electrode lead 32 is located in the hole 52 portion.
will be fitted together.

Further, the heater leads 42 are brazed to the two conductive parts 50 and 50 located inside the ceramic sheet 46 through holes (not shown) provided in the ceramic sheet 46. These are electrically connected.

In such a method of forming the heater 16 by wrapping the ceramic sheet 46, the hole 52 provided in the ceramic sheet 46 directly becomes the recess 38 of the heater 16, and the hole 52 becomes a large recess 38 which is extremely easy to form. It has advantages.

Although one or two specific examples of the present invention have been explained above, the present invention is not to be construed as being limited to these specific examples, and as long as they do not depart from the spirit of the present invention, Based on the knowledge of those skilled in the art, various changes, modifications, improvements, etc. can be made to the present invention, and the present invention includes the following:
It goes without saying that the invention also includes such embodiments.

As detailed above, in the present invention, a recess is provided on the outer surface of the heater that heats the solid electrolyte, and a part of the center electrode lead for extracting the electromotive force signal of the solid electrolyte is fitted into the recess. As a result, the heater and the center electrode lead can be effectively positioned, thereby preventing a short circuit between the heater lead and the center electrode lead, thereby facilitating the assembly work of the sensor. In addition, excellent effects such as increasing the reliability of the obtained sensor were achieved, and this is where the present invention has extremely significant industrial significance.

[Brief explanation of the drawing]

FIG. 1 is a partial sectional view showing an embodiment of the oxygen sensor according to the present invention, and FIG. 2a is a perspective explanatory view showing the center electrode lead inserted into the heater in the embodiment of FIG. , FIG. 2b is a cross-sectional explanatory diagram showing a fitting structure between such a heater and a center electrode lead, and FIGS. 3a to 3c show an example of the heater structure used in the present invention. , of which a is a partially cutaway front view showing the extrapolation and fitting state of the center electrode lead to the heater, and b is a B in a.
-B sectional view, c is a plan view showing the ceramic sheet in a state before being wound around a ceramic rod. 2...Solid electrolyte, 4...Housing, 16...
... Heater, 18, 20 ... Insulator, 24 ... Cap, 26 ... Rubber stopper, 28a, 28b, 28
c... Lead wire, 32... Center electrode lead, 34
... Pressing piece, 36 ... Protrusion, 38 ... Recess, 40
...Signal lead, 42...Heater lead, 44...
... Connector, 46... Ceramic sheet, 48...
Heat generating part, 50... Conductive part, 52... Hole, 54...
Ceramic stick.

Claims (1)

[Claims for Utility Model Registration] A cylindrical solid electrolyte with a bottom provided with predetermined electrodes on its inner and outer surfaces, and a closed end of the fixed electrolyte exposed to the gas to be measured, while the inside of the cylinder into which the atmosphere is introduced. a rod-shaped heater that is inserted into the solid electrolyte cylinder and heats the solid electrolyte; and a rod-shaped heater that is inserted over the heater and connected to the inner surface electrode. be done,
In the oxygen sensor having an annular center electrode lead for extracting an electromotive force signal of the solid electrolyte, a ceramic sheet with holes provided at predetermined positions is wound around a rod-shaped body as the heater, and the ceramic sheet is fired. Using the thus obtained heater having a heating element inside, a part of the center electrode lead is fitted into a recess formed by the hole on the outer surface of the heater. An oxygen sensor characterized in that the oxygen sensor is positioned relative to the heater.