JP2002257773A - Gas sensor and gas analytic device, and high temperature connector used therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas sensor and gas analytic device which require only the replacement of a part of the gas sensor without requiring the replacement of the whole gas sensor even in the occurrence of a failure or trouble in a part of the gas sensor and capable of extremely easily performing the replace ment, and a high temperature connector preferably applied thereto. SOLUTION: This gas sensor comprises a sensor unit 10 having a plate-like gas sensor element 11 exposed to a gas detection part 12 with the residual part thereof airtightly fixed to a cylindrical porcelain tube 13 and a sensor-side connector part A having a heat resisting electric contact 16 on the end surface of a cylindrical metal pipe 14; a probe unit 20 having a probe-side connector part B attachably and detachably mounted on the sensor-side connector part A and having an electrically connected heat resisting electric contact 21; and a filter unit 30 attachably and detachably mounted on the end surface part of the cylindrical metal pipe 14 and having a filter 31 in the part opened to a measuring gas atmosphere side.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas sensor and a gas analyzer for detecting the concentration of gas such as oxygen, carbon monoxide or carbon dioxide contained in exhaust gas discharged from an internal combustion engine or a combustion furnace, etc. More specifically, the high-temperature connector used for these components can be easily attached to and detached from a combustion furnace or a large exhaust pipe, maintenance is much easier than before, and a failure or defect occurs in a part of the gas sensor. In the event of occurrence, the gas sensor and gas analyzer can be replaced very easily without replacing the entire gas sensor, and the gas sensor and the gas analyzer can be easily replaced. The present invention relates to a connector for communication.

[0002]

2. Description of the Related Art Conventionally, a gas sensor detects the concentration of oxygen, carbon monoxide, or carbon dioxide in an exhaust gas from an internal combustion engine such as an automobile engine or a combustion furnace or an incinerator. By controlling the supply amount of oxidant air or fuel so as to optimally control the combustion state of the internal combustion engine or the like based on the detection signal, the emission of incomplete combustion gas is suppressed and the exhaust gas is purified. It is used to reduce fuel consumption.

[0003] Needless to say, such a gas sensor has high selective reactivity with the gas to be measured, is chemically stable to high-temperature exhaust gas, is easy to manufacture, and is compact. Possible ones are preferred.
Therefore, those using a solid-state sensor element are preferable,
For example, an oxygen sensor using a solid electrolyte having oxygen ion conductivity and a carbon monoxide sensor using semiconductor characteristics of tin oxide are known.

In general, a gas sensor element is easily damaged when a solid electrolyte plate, a semiconductor substrate, an electrode, or a lead wire is exposed, and is difficult to be attached to an exhaust pipe through which a gas to be measured flows. Are housed in various housings, and are used by being mounted on an actual exhaust pipe or the like. FIG. 6 is an explanatory view showing a state where the gas sensor is attached to the exhaust pipe. The gas sensor 100 is fixed to the exhaust pipe 104 by the attachment flange 102 in a state where the gas sensor 100 is inserted into the guide pipe 106. FIG. 7 is an exploded perspective view showing a joint structure between a conventionally known probe main body, a filter, and a sensor unit.
Are four bolts 120 through flanges 116 and 118
Installed with. Gas seal is metal O-
A ring 121 is used. In addition, 122 is a filter fixing net, and the filter fixing net 122 is attached so as to fix the filter 114 to the tip of the sensor unit 112 by the filter fixing bracket 124 and the bolt 126.

However, in the above-described conventional gas sensor, only the air-fuel ratio near the inner wall of the exhaust pipe or the like can be measured, and it is doubtful whether the average composition of the entire combustion gas is measured. In addition, since the insertion length of a conventional gas analyzer equipped with a gas sensor is often determined by the manufacturer's standards, the gas analyzer is installed so that the gas detector is aligned with the center of the exhaust pipe used. It becomes necessary to attach a mating flange for adjusting the position of the mounting flange.

Further, regardless of the length of the gas analyzer, when performing maintenance on the gas analyzer, the entire gas analyzer must be removed from an exhaust pipe or the like.
That is, every time the sensor unit and the filter unit are replaced, it is necessary to attach and detach the bolt and replace the metal O-ring. If the filter is used at a high temperature, the filter mounting portion may seize and the filter cannot be removed. In this case, it is necessary to replace the entire gas analyzer with a new one.

In order to solve the above-described problems, the present inventors set a plate-shaped gas sensor element so that a gas detection portion provided on the gas sensor element is exposed, and set the remaining gas sensor element to a cylindrical shape. A gas sensor, which is hermetically fixed to a porcelain insulator, and hermetically attached to the inside of a cylindrical metal pipe so as to surround the outer periphery of the cylindrical porcelain while the detection portion of the gas sensor element is in communication with the measurement atmosphere And a structure in which this gas sensor is attached to an exhaust pipe such as a pipe / duct through an inner hole of a tube joint (see Japanese Patent Application Laid-Open No. 10-227761).

The above gas sensor can be adjusted to an arbitrary length and inserted directly into a combustion section or a large exhaust pipe, and has the advantage of easy maintenance. The cylindrical metal pipe is hermetically mounted in the metal pipe, and the cylindrical metal pipe is fixed to the metal fixed pipe and the terminal box. Even if a part of the gas sensor fails, the entire gas sensor is replaced. It was necessary.

[0009]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and it is not necessary to replace the entire gas sensor when a failure or malfunction occurs in a part of the gas sensor. It is an object of the present invention to provide a gas sensor and a gas analyzer which can be replaced with a new one, and which can be replaced very easily, and a high-temperature connector which can be preferably applied thereto.

[0010]

That is, according to the present invention, a plate-shaped gas sensor element is exposed so that a gas detecting portion provided on the gas sensor element is exposed, and the remaining part of the gas sensor element is formed into a cylindrical insulator. In a state where the detection portion of the gas sensor element is in communication with the measurement atmosphere, the cylindrical insulator is hermetically mounted in a cylindrical metal pipe so as to surround the outer periphery of the cylindrical insulator, and the gas detection is performed. A sensor unit having a sensor-side connector portion having a heat-resistant electrical contact on an end surface of the cylindrical metal pipe opposite to the side where the portion is exposed; A probe unit provided with a probe-side connector portion having a heat-resistant electrical contact that is freely attached and electrically connected to the sensor-side connector portion;
A filter unit that is removably attached to an end surface of the cylindrical metal pipe on the side where the gas detection unit of the sensor unit is exposed, and that has a filter at a portion that opens to the measurement gas atmosphere side. A gas sensor is provided.

Here, a calibration gas pipe for introducing a calibration gas is attached to the filter unit, and a tip of the calibration gas pipe is preferably connected to a pipe provided in the probe unit. The connector part is attached to the probe side connector part of the probe unit through the inner hole of the tube joint, and the heat-resistant electric contact of the sensor side connector part is connected to the heat resistance of the probe side connector part provided in the tube joint. Preferably, it is electrically connected to the electric contact.

It is preferable that an end surface of the cylindrical metal pipe on the side where the gas detecting portion of the sensor unit is exposed is attached to the filter unit through an inner hole of the tube joint. Preferably, a cable electrically connected to the heat-resistant electrical contact of the probe-side connector section via a lead wire is provided. When such a sensor is attached to an exhaust pipe or the like, the probe unit is attached to an exhaust pipe such as a pipe / duct through the inner hole of the tube joint, so that the sensor can be inserted at an arbitrary length. Becomes possible.

Further, according to the present invention, a tube joint is provided on a gas analyzer mounting flange provided on an exhaust pipe, and a metal probe pipe is inserted so as to pass through a through hole of the tube joint. The probe pipe is fixed at the tube joint by aligning one end of the probe pipe with an arbitrary measurement position in the exhaust pipe, and the probe unit of the gas sensor is attached to the other end of the probe pipe. A gas analyzer characterized by the following.

Here, it is preferable that a calibration gas pipe connected to a pipe provided in the probe unit is disposed in the probe pipe, and a calibration gas is supplied by using a tip of the calibration gas pipe as a calibration gas inlet. .

Further, according to the present invention, there is provided a high-temperature connector for use in a gas sensor, which comprises a pair of connector members, and one of the insertion-side connector members has a heat-resistant electrical connector having a convex end portion. The contact is buried in the electrically insulating member leaving the tip convex portion, and the heat-resistant electrical contact and the electrically insulating member are fixed in a metal pipe, and the other spring-side connector member is A heat-resistant electrical contact formed in a concave shape so as to receive and electrically contact the tip convex portion is embedded in an electrically insulating member, and the heat-resistant electrical contact and the electrically insulating member are made of metal. A high-temperature connector characterized by being fixed in a pipe is provided.

In the above-described high-temperature connector, the tip convex portion of the heat-resistant electric contact of the insertion-side connector member is inserted into the concave heat-resistant electric contact of the spring-side connector member. It is preferable that the spring load of the heat-resistant electric contact of the spring-side connector member is applied to the tip convex portion of the heat-resistant electric contact of the insertion-side connector member, and that the electric connection be reliably performed. It is divided into a sensor unit and a probe unit,
It is preferable that the sensor unit is provided with the spring-side connector member, and the probe unit is provided with the insertion-side connector member.

[0017]

Hereinafter, the present invention will be described with reference to the drawings, but the present invention is not limited to these embodiments.

FIGS. 1A, 1B, and 1C are cross-sectional views showing one embodiment of a gas sensor according to the present invention.
FIG. 1B is a sectional view of the filter unit, FIG. 1B is a sectional view of the sensor unit, and FIG. 1C is a sectional view of the probe unit. As shown in FIG. 1B, the sensor unit 10
Replaces the plate-shaped gas sensor element 11 with the gas sensor element 11.
The remaining gas sensor element 11 is hermetically fixed to a cylindrical insulator tube 13 so that the gas detector 12 provided in the cylindrical sensor tube 11 is exposed, and the detection portion of the gas sensor element 11 is communicated with the measurement atmosphere. A cylindrical insulator tube 13 is hermetically mounted in a cylindrical metal pipe 14 so as to surround the outer periphery. The remaining part of the gas sensor element 11 is inserted into the cylindrical insulator 13 so as to be fixed in the cylindrical insulator 13,
The gap 15 formed between them is filled with glass or talc and hermetically sealed. As the cylindrical insulator tube 13, an alumina tube is preferably used.

The gas detector 1 of the cylindrical metal pipe 14
The cylindrical metal pipe 14 on the side opposite to the side where 2 is exposed
A spring-side (concave) heat-resistant electrical contact 16
Is connected to the gas sensor element 11
And is connected to a lead wire 17 extending from the electrode.

FIG. 1C shows a probe unit 20. The probe unit 20 has a structure that can be detachably attached to the sensor-side connector portion A of the sensor unit 10 described above. A probe-side connector section B having an insertion-side (convex) heat-resistant electrical contact 21 electrically connected to the sensor-side connector section A is provided.

The sensor-side connector portion A of the sensor unit 10 is connected to the probe-side connector portion B of the probe unit 20 through the inner hole of the tube joint 22, and the probe-side connector provided in the tube joint 22. It can be electrically connected to the heat-resistant electric contact 21 of the part B. Further, the probe unit 20 is provided with a cable 26 electrically connected to the heat-resistant electrical contact 21 of the probe-side connector B via the lead wire 25. The cable 26 is configured such that a lead wire 25 is inserted into a cylindrical metal pipe 28, and a gap is filled with magnesium oxide 29. In addition, both ends of the cable 26 are ceramic adhesive, silicon adhesive,
Magnesium oxide 2 using airtight glass, brazing material, etc.
9 is hermetically sealed, insulated between the lead wires 25, and moisture-proofed to the outside.

FIG. 1A shows a filter unit 30. The filter unit 30 is provided with a tube at the end face of the cylindrical metal pipe 14 on the side where the gas detection unit 12 of the sensor unit 10 is exposed. It has a structure that can be detachably attached through the inner hole of the joint 34,
A filter 31 is provided in a portion that opens to the measurement gas atmosphere side. A calibration gas pipe 32 for introducing a calibration gas is attached to the filter unit 30, and a tip of the calibration gas pipe 32 is connected to the calibration gas pipe 24 provided in the probe unit 20.

The sensor unit 1 described above
0, probe unit 20, and filter unit 30
FIG. 2 shows a gas sensor configured by connecting and integrating the gas sensors.

As the sensor element of the gas sensor according to the present invention, a conventionally known sensor element is used. As the solid electrolyte plate to be used, a material having high oxygen ion conductivity is used, and in general, stabilized zirconia excellent in high-temperature stability and chemical stability is preferably used. Platinum excellent in catalytic reactivity with oxygen and heat resistance is suitably used for the electrode,
As the lead wire, platinum or a platinum-based alloy having excellent stability at high temperatures, and a nickel wire or a nickel alloy wire that is inexpensive and has excellent heat resistance are suitably used, and the length is
It suffices if the voltage drop caused by the resistance of the current and voltage leads detected by the sensor element is within a range that does not hinder the determination of the oxygen concentration.

FIG. 3 is an explanatory side view showing an embodiment of the gas analyzer according to the present invention. First, a tube joint 42 is provided on a gas analyzer mounting flange 41 provided on an exhaust pipe (not shown), and a metal probe pipe 43 is inserted through a through hole of the tube joint 42. The flange 41 is fixed to an exhaust pipe or the like using a bolt or the like. The probe pipe 43 is fixed to the tube joint 42 at one end of the metal probe pipe 43 at an arbitrary measurement position in the exhaust pipe. In the probe pipe 43, a calibration gas pipe 47 is disposed, and a pipe 24 (FIG. 1) provided in the probe unit 20 is provided.
(See (a)), the tip of the calibration gas pipe 47 serves as a calibration gas inlet 48, from which the calibration gas is supplied into the gas sensor 45 via the filter unit 30. At the other end of the probe pipe 43, a probe unit 20, which forms a part of the gas sensor 45, is attached. Thus, the mounting flange 41, the probe pipe 43 and the gas sensor 4
5 is formed.

Therefore, in the gas analyzer of the present invention, when the tube joint 42 is used, the gas sensor 4
5 can be freely adjusted within the range of the length of the probe pipe 43 to which the gas sensor 45 is attached, and the gas concentration analysis of the combustion gas at an arbitrary position in the exhaust pipe becomes possible.

A cable 26 extending from the probe unit 20 is inserted into the probe pipe 43, and the cable 26 is connected to a terminal head (terminal block) 4.
9 is fixed.

In the gas sensor and the gas analyzer of the present invention described above, the following high-temperature connector is suitably used. 4 (a) and 4 (b) are cross-sectional views showing one embodiment of the high-temperature connector according to the present invention, and FIGS. 5 (a) to 5 (f) are AA cross sections in FIGS. 4 (a) and 4 (b), respectively. Figure, B-
It is B sectional drawing, CC sectional drawing, DD sectional drawing, EE sectional drawing, and FF sectional drawing.

The high temperature connector includes a pair of connector members 51 and 52. One insertion-side connector member 51 has a heat-resistant electric contact 53 formed in a thin rod shape at the tip, and is buried in an electrically insulating member 54 except for a rod-shaped tip 53a. The electrically insulating member 54 is fixed in a cylindrical metal pipe 55.

On the other hand, the spring-side connector member 52 has a distal end rod-like portion 53 a so that the distal end rod-like portion 53 a of the above-mentioned heat-resistant electric contact 53 can be inserted and electrically connected reliably.
The heat-resistant electric contact 56 formed so as to have a so-called twin spring structure 56a to which a vertical spring load is applied when a is inserted is embedded in the electric insulating member 57, and the heat-resistant electric contact 56 and the electric insulating The elastic member 57 is similarly fixed in a cylindrical metal pipe 58.

Here, in the embodiment of FIGS. 1A, 1B, and 1C, the insertion side connector member 51 shown in FIG. 4A is connected to the probe unit 20 side of FIG. 1C. The spring-side connector member 52 shown in FIG. 4B is used as the heat-resistant electric contact 21 on the sensor unit 10 side in FIG. 1B.

The heat-resistant electrical contact used for the high-temperature connector is not particularly limited as long as it is made of a heat-resistant material having electrical conductivity.
Since a material having a spring property is preferable, Ni 50%
As described above, those made of an alloy containing 15% or more of Cr are preferable. In addition, the heat-resistant electrical contact is preferably subjected to platinum plating as a base plating for gold plating from the viewpoint of improving oxidation resistance and wear resistance as compared with nickel base plating. Further, the material of the electrically insulating member used for the high-temperature connector is not particularly limited as long as it is a material having electrical insulation, and a ceramic material or the like is used, for example, containing 90% or more of Al ₂ O _3. Porcelain is preferably used.

Although the gas sensor and gas analyzer of the present invention and the high-temperature connector used for the same have been described in detail above, it goes without saying that the present invention is not limited by these embodiments. . In addition, it is understood that various changes, modifications, improvements, and the like can be made to the present invention based on the knowledge of those skilled in the art without departing from the spirit of the present invention, in addition to the above-described embodiments. It should be.

[0034]

As described above, according to the gas sensor of the present invention, maintenance is extremely easy as compared with the related art, and even if a failure or malfunction occurs in a part of the gas sensor, the entire gas sensor is replaced. There is an advantage that there is no need to perform the process and only a part of the process needs to be replaced.
When a tube joint is used for connection between the filter unit, the sensor unit and the probe unit, the attachment and detachment are one-touch, and the maintainability is extremely excellent. Also, because the tube fitting can be attached and removed many times,
Even when a failure or failure occurs in each unit, there is an advantage that consumable parts such as an O-ring and a packing which are conventionally required each time are not generated.

Further, the gas sensor and the gas analyzer of the present invention can be easily attached to and detached from a combustion furnace or a large exhaust pipe, and when gas sensors of various lengths are required depending on the use mode. Even in this case, there is an effect that it is only necessary to assemble products in a range where the length adjustment ranges of the probe units do not overlap.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing one embodiment of a gas sensor according to the present invention, wherein (a) is a cross-sectional view of a filter unit, and (b)
Is a sectional view of the sensor unit, and (c) is a sectional view of the probe unit.

FIG. 2 is a cross-sectional view showing one embodiment of the gas sensor of the present invention in which the filter unit, the sensor unit and the probe unit shown in FIGS. 1 (a), (b) and (c) are connected.

FIG. 3 is an explanatory side view showing one embodiment of the gas analyzer according to the present invention.

FIGS. 4A and 4B are cross-sectional views showing one embodiment of a high-temperature connector according to the present invention, in which FIG. 4A is a cross-sectional view showing one embodiment of an insertion-side connector member, and FIG. FIG.

FIGS. 5A to 5F are FIGS. 4A and 4B, respectively.
AA sectional view, BB sectional view, CC sectional view at
It is DD sectional drawing, EE sectional drawing, FF sectional drawing.

FIG. 6 is an explanatory view showing a state in which a conventionally known gas sensor is attached to an exhaust pipe.

FIG. 7 is an exploded perspective view showing a joint structure of a conventionally known probe body, a filter, and a sensor unit.

[Explanation of symbols]

10 ... Sensor unit, 11 ... Gas sensor element, 12 ...
Gas detector, 13: cylindrical insulator pipe, 14: cylindrical metal pipe, 15: gap (filled with glass), 16: spring side (concave)
Heat-resistant electrical contacts 17; lead wires 20; probe units 21; heat-resistant electrical contacts 21 on the insertion side (convex);
22 ... tube fitting, 24 ... calibration gas pipe, 25 ... lead wire, 26 ... cable, 28 ... cylindrical metal pipe, 2
9 ... magnesium oxide, 30 ... filter unit, 31
... Filter, 32 ... Calibration gas pipe, 34 ... Tube fitting, 40 ... Gas analyzer, 41 ... Mounting flange for gas analyzer, 42 ... Tube fitting, 43 ... Metal probe pipe, 45 ... Gas sensor, 47 ... Calibration gas pipe, 48
... Calibration gas inlet, 49 ... Terminal head (terminal block), 51 ... Insertion side connector member, 52 ... Spring side connector member, 53 ... Heat-resistant electrical contact, 53a ... Tip-shaped end of heat-resistant electrical contact 53, 54 ... electric insulating member, 55
... cylindrical metal pipe, 56 ... heat-resistant electrical contact, 56
a: twin spring structure, 57: electrical insulating member, 58: cylindrical metal pipe, A: sensor side connector, B: probe side connector, 100: gas sensor, 102: mounting flange, 104: exhaust pipe, 106 ... Guide pipe, 1
10: Probe body, 112: Sensor unit, 114
... Filters, 116, 118 ... Flange, 120 ... Bolt, 121 ... Metal O-ring, 122 ... Filter fixing net, 124 ... Filter fixing bracket, 126 ... Bolt.

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2G004 BB04 BC02 BC09 BD06 BF30 BH01 2G046 AA03 AA11 BA01 BA09 BB02 BC07 BD02 BH03 BJ07 EB01 FB02 FE39 2G060 AA03 AB08 AE19 BA01 BB13 BD08 BD10 KA01

Claims (11)

[The claims] 1. A gas sensor element having a plate-like shape so that a gas detecting portion provided on the gas sensor element is exposed, and the remaining part of the gas sensor element is air-tightly fixed to a cylindrical insulator tube. While communicating with the measurement atmosphere, the cylindrical insulator tube is hermetically mounted in a cylindrical metal pipe so as to surround the outer periphery of the cylindrical insulator tube, and the gas detector is on the opposite side to the exposed side. A sensor unit having a sensor-side connector portion having a heat-resistant electrical contact on an end surface of the cylindrical metal pipe; and a sensor unit detachably attached to the sensor-side connector portion of the sensor unit. Unit provided with a probe-side connector portion having a heat-resistant electrical contact for electrical connection, and the cylindrical shape on the side where the gas detection portion of the sensor unit is exposed Removably attached to the end face of the genus pipes, gas sensor characterized by comprising a filter unit having a filter portion which opens into the measurement gas atmosphere side. 2. The filter unit is provided with a calibration gas pipe for introducing a calibration gas, and a tip of the calibration gas pipe is connected to a pipe provided in the probe unit. 2. The gas sensor according to 1. 3. The sensor-side connector section of the sensor unit is attached to the probe-side connector section of the probe unit through an inner hole of a tube joint, and the heat-resistant electrical contact of the sensor-side connector section is The gas sensor according to claim 1, wherein the gas sensor is electrically connected to a heat-resistant electric contact of a probe-side connector provided in the tube joint. 4. An end face of the cylindrical metal pipe on a side where a gas detecting portion of the sensor unit is exposed is attached to the filter unit through an inner hole of a tube joint. The gas sensor according to claim 1. 5. The probe unit according to claim 1, wherein a cable electrically connected via a lead wire from a heat-resistant electric contact of the probe-side connector is disposed in the probe unit. The gas sensor according to claim 1. 6. The gas sensor according to claim 1, wherein the probe unit is attached to an exhaust pipe such as a pipe / duct through an inner hole of a tube joint. 7. A tube joint is provided on a gas analyzer mounting flange provided on an exhaust pipe, and a metal probe pipe is inserted through a through hole of the tube joint, and one of the probe pipes is inserted. The probe pipe is fixed at the tube joint with its tip aligned with an arbitrary measurement position in the exhaust pipe, and the probe unit of the gas sensor according to any one of claims 1 to 5, at the other end of the probe pipe. A gas analyzer characterized by being attached. 8. A calibration gas pipe connected to a pipe provided in the probe unit is disposed within the probe pipe, and a calibration gas is supplied by using a tip of the calibration gas pipe as a calibration gas inlet. The gas analyzer according to claim 7, wherein: 9. A high-temperature connector for use in a gas sensor, comprising a pair of connector members, wherein one of the insertion-side connector members comprises a heat-resistant electric contact having a tip formed in a convex shape. The heat-resistant electrical contact and the electrical insulating member are fixed in a metal pipe while leaving the resilient portion, and the other spring-side connector member is the above-mentioned convex portion at the tip. A heat-resistant electric contact formed in a concave shape so as to receive and electrically contact is embedded in an electric insulating member, and the heat-resistant electric contact and the electric insulating member are fixed in a metal pipe. A high-temperature connector characterized in that: 10. The heat-resistant electric contact of the insertion-side connector member is inserted into the concave heat-resistant electric contact of the spring-side connector member so that the heat-resistant electric contact of the spring-side connector member is inserted. 10. The high-temperature connector according to claim 9, wherein a spring load of the non-contact electric contact is applied to a tip convex portion of the heat-resistant electric contact of the insertion-side connector member so as to reliably perform electric connection. 11. The gas sensor is divided into at least a sensor unit and a probe unit, wherein the sensor unit is provided with the spring-side connector member, and the probe unit is provided with the insertion-side connector member. The high-temperature connector according to claim 9 or 10, wherein