DE102011083373A1 - Temperature sensor for measuring temperature of exhaust gas from vehicle, has sintered ceramic insulation pipe that is arranged in cylindrical structure, and is supported by supporting component - Google Patents

Abstract

A sintered ceramic insulation pipe (4) arranged in cylindrical structure (2) includes a pair of penetration holes penetrating the cylindrical structure in axial direction. The signal lines (5) are penetrated through penetration hole and connected with thermal sensor arranged in closed end of cylindrical structure. Spacing (10) is formed between inner circumferential surface (20) of cylindrical structure and peripheral surface (45) of insulation pipe. A supporting component (6) made of metal or braided fabric is arranged in cylindrical structure to support insulation pipe in spacing.

Description

Background of the invention

Technical field of the invention

The present invention relates to a temperature sensor provided with a thermal sensor, an insulation tube having holes, and signal wires of the thermal sensor inserted into the penetration holes.

Description of the Related Art

A temperature sensor for measuring the temperature of exhaust gas, etc. of vehicles is known as in 10 is shown, and the sensor is equipped with a thermal sensor 93 such as a thermistor, etc. and a shielding pin 90 provided (see JP 2000-162051 ).

The shielding pin 90 is with a cylindrical component made of metal 92 , a powdery insulator 94 placed in the interior of the cylindrical component 92 filled in, and a pair of signal lines (wires) 95 that with a thermosensor 93 are provided, provided. The position of the pair of signal lines 95 is supported and the pair has insulation properties passing through the insulator 94 be maintained.

If the shielding pin 90 is produced, a so-called deep drawing process is carried out.

That is, a cylindrical member having a larger outer diameter than the machined cylindrical members 92 and with a shorter length with respect to an axial direction, the pair of signal lines is provided 95 is passed through the cylindrical member and the powdered insulator 94 which is composed of MgO, etc. is filled in it.

Then, a thickness reduction process is performed on the outer diameter of the cylindrical member and a stretching process on the length of the cylindrical member in the axial direction.

It is made by deep drawing, which is the insulator 94 close and close to the cylindrical component 92 power, prevents the insulator 94 from the cylindrical component 92 removed or deducted or falls out of this.

On the other hand, a rib part 98 around the shielding pin 90 arranged around and is an outer cylinder 900 on the rib part 98 fixed.

A rear end section 90a of the shielding pin 90 is in the outer cylinder 900 used.

A sleeve made of rubber 99 is in a rear end 905 of the outer cylinder 900 arranged.

Connecting cables (wires) 96 that with an insulating film 960 are coated with the signal lines 95 connected and step through the sleeve 99 inside her.

Furthermore, a crimping process at the rear end 905 of the outer cylinder 900 executed to prevent the sleeve 99 and the wires 96 slip out.

The temperature sensor 91 is in an exhaust pipe 97 a vehicle (not shown).

The temperature of an exhaust gas g (measured body) in the exhaust pipe 97 flows, is with the thermal sensor 93 is measured and used for controlling an internal combustion engine, etc.

However, the usual temperature sensor 91 a problem that its manufacturing cost is expensive because the deep-drawing process is required when the shielding pin 90 will be produced.

Furthermore, there is a problem of easy moisture absorption, as in the usual temperature sensor 91 powdered ceramic as the insulator 94 in the shielding pin 90 is used.

If the insulator 94 Moisture absorbs, it becomes difficult the insulation properties between the pair of signal lines 95 sure.

As the insulating properties decrease, an electric current flows between the pair of signal lines 95 whereby the problem arises that it becomes impossible to output an accurate detection voltage.

In addition, the usual temperature sensor has 91 the problem is that heat is simply from the insulator 94 to the cylindrical component 92 is passed as the insulator 94 in the cylindrical component 92 filled in with no gaps.

Therefore, the heat of the thermal sensor 93 from the insulator 94 to the cylindrical component 92 , then to the rib part 98 and into the exhaust pipe 97 passed in this order and the heat is radiated to environments of the cylindrical member or an outside of the exhaust pipe, which causes the temperature of the thermal sensor 93 just drops off.

As a result, a long time is required until the temperature of the thermal sensor 93 and the temperature of the exhaust gas g become the same.

Therefore, when the temperature of the exhaust gas g changes, it is difficult to detect the temperature rapidly after the change thereof.

That is, the problem of poor response to the temperature change of the exhaust gas g is caused.

Furthermore, it is when the heat is simply from the insulator 94 to the cylindrical component 92 It is simply passed to the temperature of the exhaust gas, that to the insulator 94 can be performed. Because the heat through the insulator 94 directed to an upper part of the temperature sensor, the temperature of parts outside the exhaust pipes 93 such as the sleeve 99 and the wires 96 , are arranged, just rise.

Therefore, it is necessary to use parts with high heat resistance, thereby reducing the cost of manufacturing the temperature sensor 91 climb.

Summary of the invention

The present invention is made in view of the above problems and its object is to provide a temperature sensor which reduces the manufacturing cost, easily ensures the isolation characteristics of signal lines and excellently responds to the temperature change of a measured body.

In a temperature sensor according to a first aspect, the temperature sensor comprises a cylindrical member having an end that is closed, a thermal sensor disposed in the cylindrical member, an insulation tube made of a sintered ceramic body disposed in the cylindrical member having a pair of penetrating holes penetrating through the cylindrical member in an axial direction and a pair of signal wires (wires) connected to the thermal sensor and passing through the penetrating hole of the insulating pipe ,

At least in a part of a region in the axial direction of the insulating tube, a clearance (space) is formed between an inner peripheral surface of the cylindrical member and a peripheral surface of the insulating tube, and a support member that supports the insulating tube with a clearance (spaced supports) formed between the cylindrical members is disposed in the cylindrical member.

According to the present invention, a powdery ceramic is not used, but the insulating tube made of the sintered ceramic body is used to ensure electrical insulation between the pair of signal lines.

The signal lines pass through the penetration holes arranged in the insulation tube.

Since the insulating tube is made of the sintered ceramic body, the insulating tube can not easily absorb moisture when the above-mentioned structure is used, and it is more difficult to deteriorate the insulating properties between the pair of signal lines.

Furthermore, since it is not necessary according to the present invention to carry out the above-described deep drawing process, the manufacturing cost of the temperature sensor can be reduced.

Further, at least in the part of the region in the axial direction of the insulating tube, the distance between the inner peripheral surface of the cylindrical member and the peripheral surface of the insulating tube according to the present invention is formed.

Since the clearance (space) between the cylindrical member and the insulating tube is formed as described above, heat is hardly conducted from the insulating tube to the cylindrical member.

Therefore, disadvantages of passing the heat of the temperature sensor to the electrical component through the insulating tube and radiating the heat around the cylindrical member or conducting the heat to the fin part and the exhaust pipe and radiating the heat from the exhaust pipe can be prevented.

As a result, the temperature of the thermal sensor and the temperature of the measured body quickly become equal, and as the temperature of the measured body changes, it is possible to quickly detect the temperature after the change thereof. That is, the response to the temperature change of the measured body improves.

Furthermore, the temperature sensor of the present invention has the support member that supports the insulation tube.

Therefore, even if some vibration force applied to the temperature sensor from the outside and causing the temperature sensor to vibrate, the insulation tube can be supported by the cylindrical member.

Therefore, it becomes difficult for the insulating tube to reciprocate in the radial direction, and even if a thin and long insulating tube is used, it is difficult for the insulating tube to be damaged.

Further, the support member supporting the insulation tube is provided with a clearance between the support member and the cylindrical member (spaced apart).

Therefore, the stress due to the vibration can be reduced by adjusting the position of the support member and the size of the gap.

As a result, the disadvantages that the insulation tube breaks or that the lead wires are broken can be prevented even when there is a condition where a high vibration stress occurs.

As mentioned above, according to the present invention, the temperature sensor can be provided at a reduced manufacturing cost, further, it is easy to secure the isolation of the signal lines, and furthermore the temperature sensor has a good response to the temperature change of the measured body.

In the temperature sensor according to a second aspect, the diameter of a portion where the thermal sensor is disposed of the cylindrical members is smaller than the diameter of a portion where the clearance is formed.

In the temperature sensor according to a third aspect, the portion where the temperature sensor is disposed inside and the portion where the space between the peripheral surfaces of the insulating tube of the cylindrical member is formed are integrally formed.

In the temperature sensor according to a fourth aspect, the support member has a cylinder-side portion, an insulating pipe portion and a connecting portion.

The cylinder-side portion fixes the support member to the cylindrical member by pressing the inner peripheral side of the cylindrical member outward in a radial direction.

The insulating pipe section surrounds the peripheral surface of the insulating tube.

The connecting portion connects the cylinder-side portion and the isolated, cylinder-side portion.

In the temperature sensor according to a fifth aspect, the support member is made of a body having elasticity (spring force).

In the temperature sensor according to a sixth aspect, the support member is made of a metal mesh in which small caliber metal wires are entangled.

In the temperature sensor according to a seventh aspect, a high heat conductive material whose thermal conductivity is higher than air is filled between an inner peripheral surface of the cylindrical member and an outer surface of the thermal sensor.

Brief description of the drawings

The accompanying drawings show:

1 shows a sectional view of a temperature sensor in a first embodiment;

2 shows an enlarged sectional view of a basic part of 1 ;

3 shows an enlarged perspective view of an insulating tube in the first embodiment;

4 shows an enlarged view of a support member in the first embodiment;

5 shows a perspective view of the support member in the first embodiment;

6 shows an enlarged sectional view of a basic part of the temperature sensor in a second embodiment;

7 shows an enlarged sectional view of a basic part of the temperature sensor in a third embodiment;

8th shows an enlarged sectional view of a basic part of the temperature sensor in a third embodiment in which a highly heat conductive material is filled in a second part of a cylindrical part;

9 shows an enlarged sectional view of a basic part of the temperature sensor in a fourth embodiment; and

10 shows a sectional view of a temperature sensor according to the prior art.

Detailed Description of the Preferred Embodiments

Referring to the drawings, the embodiments of the present invention will be described below.

(First embodiment)

A temperature sensor according to a first embodiment of the present invention will be described below 1 to 5 explained.

The temperature sensor 1 of the present embodiment has a cylindrical member 2 that's an end 21 which is closed, a thermal sensor 3 which is in the cylindrical component 2 is arranged, an insulation tube (spaghetti) 4 and a pair of signal lines (signal wires) 5 , as in 1 and 2 is shown.

The insulation pipe 4 made of a sintered ceramic body is in the cylindrical member 2 arranged and has a pair of penetration holes 40 passing in an axial direction X through the cylindrical member 2 pass through (see 3 ).

The insulation pipe 4 is made of the ceramics having heat resistant properties such as Al ₂ O ₃ (alumina), MgO (magnesia), ZrO ₂ (zirconia), Si ₃ N ₄ (silicon nitride), and the like.

In the above-mentioned ceramics, Al ₂ O _{3 is} preferably used because of the high insulation resistance and the excellent processability.

For example, as the density of the sintered ceramic body increases, the insulating properties and the moisture absorption resistance properties can be improved.

Therefore, it is extremely preferable that the density of the sintered ceramic body is higher.

Furthermore, the signal lines 5 with the thermosensor 3 connected and pass through the penetration holes 40 of the insulation tube 4 therethrough.

The signal lines 5 are made, for example, from refractory metals such as INCONEL 601 (registered trademark) and FeCrAl.

As in 1 is shown is at least in a part of the area in the axial direction X of the insulating tube 4 a distance (space or space) 10 between an inner peripheral surface 20 of the cylindrical component 2 and a peripheral surface 45 of the insulation tube 4 educated.

Furthermore, a support member 6 that the isolation pipe 4 supports, in the cylindrical component 2 arranged, such that the distance 10 between the cylindrical components 2 is trained.

Details are explained below.

The temperature sensor 1 The present embodiment is in an exhaust pipe 7 of a vehicle (not shown) and measures the temperatures of an exhaust gas g (measured body of the present embodiment) contained in the exhaust pipe 7 flows.

Furthermore, the cylindrical component sits down 2 of the present embodiment of a first part 2a in which the thermosensor 3 is included, and a second part 2 B together, its end at the first part 2a is fixed to an inner side of the first part.

As in 2 shown are the first part 2a and the second part 2 B by laser welding, etc. at a welding section 250 welded.

The distance 10 is in all areas in (along) the axial direction X of the second part 2 B educated.

Furthermore, a diameter of an end side (part) of the first part 2a reduced compared to an end part 23 of the second part 2 B and is the insulation tube 4 used in the part whose diameter is reduced (part with reduced diameter).

To the insulation pipe 4 in the reduced diameter portion, the inner diameter of the reduced diameter portion is made slightly larger than the outer diameter of the insulating tube 4 ,

Therefore, there is a gap of about 0.5 mm to 1.0 mm between the reduced diameter part and the insulation tube 4 ,

The thermosensor 4 is made of a thermistor. The thermosensor 3 is between an end 41 of the insulation tube 4 and an end 21 of the cylindrical component 2 arranged.

Furthermore, a damping material 11 with a high thermal conductivity between the end (tip) 21 of the cylindrical component 2 and the thermal sensor 3 filled.

On the other hand, as in 1 shown is a rib 12 projecting outward in a radial direction on the cylindrical member 2 educated.

An outer cylinder 8th is at a rear end portion 12a the rib 12 fixed on the outer side. Furthermore, a fastening component 13 , which has a male thread section 130 has, on the outer cylinder 8th fixed on its outer side.

Furthermore, there is a screw hole 70 formed, which is the exhaust pipe 7 penetrates. A diameter of an inner section 72 of the screw hole 70 is reduced.

When the temperature sensor 1 at the exhaust pipe 7 is attached, the temperature sensor 1 from the outside of the exhaust pipe 7 used and becomes the fastening component 13 with the screw hole 70 screwed.

Thus, a storage area acts 71 of the above-mentioned inner portion 72 with the rib 12 together.

As a result, the exhaust gas g is prevented from flowing out to the outside.

Furthermore, a sleeve made of rubber 14 at a rear end part 80 of the outer housing 8th appropriate.

Connecting cables (wires) 15 pass through the sleeve 14 therethrough. The connecting cables 15 are with the signal lines 5 connected.

Furthermore, the end part 80 of the outer housing 8th pressed. This will prevent the sleeve 14 and the connecting cables 15 slip out.

The support component 6 is at a rear end side of the rib part 12 mounted in the axial direction X as in 1 is shown. The support component 6 is made of a body that has elasticity (spring force).

Furthermore, as in 4 and 5 is shown, the support member 6 a cylinder-side section 6a , an insulation pipe section 6b and a connection section 6c ,

The cylinder-side section 6a fixes the support component 6 on the cylindrical component 2 by pushing outward on the inner peripheral side 20 of the cylindrical component 2 in a radial direction.

The insulation pipe section 6b surrounds the peripheral surface 45 of the insulation tube 4 , The connecting section 6c connects the cylinder-side section 6a and the isolated, cylinder-side section 6b ,

Furthermore, engagement hooks (lugs) 6d projecting outward in the radial direction at a rear end portion of the cylinder-side portion 6a educated.

If the support member 6 in the cylindrical component 2 is used when the temperature sensor 1 is produced, grab the engagement hooks 6d in the rear end side 22 of the cylindrical component 2 one, leaving the support member 6 can not be moved to the end side (side of the top). This will be the support member 6 positioned.

The operation and effect of the present invention will be explained below.

As in 1 and 2 is shown, according to the present embodiment powdered ceramics are not used, but is the insulating tube 4 used, which is made of the sintered ceramic body.

The signal lines 5 pass through the penetration holes 40 passing through that in the insulation tube 4 are arranged.

Because the insulation tube 4 Made from the sintered ceramic body, it is difficult for the insulating tube 4 absorbs moisture when the above-mentioned structure is used, and it is difficult that the installation characteristics between the pair of signal lines 5 fall off.

Furthermore, since it is not necessary according to the present embodiment to carry out the deep drawing process as described above, the manufacturing cost of the temperature sensor 1 be reduced.

Further, at least in a part of the area in the axial direction X of the insulation tube 4 the distance 10 between the inner peripheral surface 20 of the cylindrical component 2 and the peripheral surface 45 of the insulation tube 4 formed in the present embodiment.

Because the distance 10 between the cylindrical component 2 and the insulation tube 4 According to the above, the heat hardly becomes from the insulating tube 4 to the cylindrical component 2 directed.

Therefore, disadvantages of passing the heat of the thermal sensor 3 to the cylindrical component 2 through the insulation tube 4 and radiating the heat around the cylindrical member 2 be prevented around.

As a result, when the temperature of the thermal sensor 3 and the temperature of the measured body (exhaust gas g) becomes slightly the same, and when the temperature of the measured body changes, it is possible to detect the temperature rapidly after its change.

That is, the response to the temperature change of the measured body improves.

Further, if it is difficult, the heat from the installation pipe 4 to the cylindrical component 2 to conduct, a temperature of the sleeve 14 or the connecting cables 15 , etc., not just high (ie it does not increase strongly).

Therefore, it is not necessary the sleeve 14 , etc., with a high heat resistance, and can reduce the manufacturing cost of the temperature sensor 1 be lowered.

Furthermore, the temperature sensor has 1 of the present embodiment, a support member 6 that the isolation pipe 4 supports.

Therefore, even if a certain vibration force on the temperature sensor 1 is applied from the outside and causes the temperature sensor 1 is vibrated, the insulation tube 4 through the (on) the cylindrical component 2 be supported.

Therefore, it becomes difficult for the insulation tube 4 is reciprocated in the radial direction, and even if a thin and long insulating tube 4 is used, it is difficult for the insulation tube 4 is damaged.

As in 1 and 2 is shown is the diameter of a section in which the thermal sensor 3 from the cylindrical components 2 is arranged smaller than the diameter of a section in which the distance 10 is formed in the present embodiment.

Because the gap between the thermal sensor 3 and the cylindrical component 2 Due to the above, the temperature of the measured body and the temperature of the thermal sensor become 3 easy (fast) the same size.

Therefore, the response to the temperature change of the measured body is much better.

Furthermore, as in 4 and 5 is shown, the support member 6 the cylinder-side section 6a , the insulation pipe section 6b and the connecting section 6c ,

The cylinder-side section 6a fixes the support component 6 on the cylindrical component 2 by pushing the inner peripheral side outwards 20 of the cylindrical component 2 in the radial direction.

The insulation pipe section 6b surrounds the peripheral surface 45 of the insulation tube 4 , The connecting section 6c connects the cylinder-side section 6a and the isolated, cylinder-side section 6b ,

Since the cylinder-side section 6a the inner peripheral side 20 of the cylindrical component 2 in the radial direction, as mentioned above, the support member is 6 through the cylinder-side section 6a firmly on the cylindrical component 2 fixed.

Therefore, mispositioning of the support member occurs 6 barely on, even if the temperature sensor 1 is vibrated.

Furthermore, because of the isolated, cylinder-side section 6b has a shape, the peripheral surface 45 of the insulation tube 4 just surround it, the insulation pipe 4 to support.

Furthermore, in the present embodiment, the support member 6 at the rear end side of the rib part 12 mounted in the axial direction X as in 1 is shown.

Since the rib part 12 the exhaust gas touches g, the temperature rises relatively easily. On the other hand, since the section on the rear side of the rib part 12 not touched the exhaust g, the temperature does not rise easily.

Therefore, if the support member 6 at the rear of the ribbed part 12 is arranged, the support member 6 be used with a low heat resistance. Thus, the manufacturing cost of the temperature sensor 1 be reduced.

Furthermore, since the support member 6 is made of the body having an elasticity (spring force) in the present embodiment, the vibration absorbing effect of the support member 6 high.

Therefore, there may be disadvantages in terms of damage to the insulation tube 4 be prevented by a vibration, even if the thin and long insulation tube 4 is used.

As mentioned above, according to the present embodiment, the temperature sensor can be provided with a reduced manufacturing cost, in which it is easy to ensure the isolation of the signal line, and with a good response to the temperature change of the measured body.

Second Embodiment

The present embodiment is an example in which the support member 6 is changed.

As in 6 is shown is the support member 6 of the present embodiment made of a metal mesh in which small caliber metal wires are entangled.

As a result, a vibration resistance of the temperature sensor 1 be improved.

That is, since the metal mesh tends to widen the selection of a metal material, the metal mesh may be formed by a metal material having a high heat resistance.

Therefore, the support member 6 , which is made of metal mesh, in the position closer to the thermal sensor 3 be formed, ie, the position in which the temperature is simply high (higher).

This represents the position for supporting the insulation tube 4 and it is possible the natural frequency of the temperature sensor 1 adjust.

Therefore, if the temperature sensor 1 For example, in a vehicle, the resonance of the vehicle and the natural frequency of the temperature sensor is used 1 can be offset and the disadvantages of the temperature sensor 1 , which are caused by a resonance at a vibration of the vehicle can be prevented.

Therefore, the vibration resistance of the temperature sensor 1 be improved.

In addition, for example, the metal mesh may be formed by the metal material having a high heat resistance such as INCO 601 (registered trademark).

The rest of the structure, the operation and the effect are the same as in the first embodiment.

(Third Embodiment)

The present embodiment is an example in which a highly heat conductive material 19 in which a thermal conductivity is higher than air, between an inner peripheral surface of the first part 2a of the cylindrical component 2 and an outer surface of the thermal sensor 3 is filled in, as in 7 is shown.

For the highly heat-conductive material 19 For example, alumina (Al ₂ O ₃ ) can be used.

Further, a gap of about 0.5 mm to 1.0 mm (not shown), for example, between the reduced diameter part of the first part 2a and the insulation tube 4 trained and is also the highly heat conductive material 19 filled in the gap in the present embodiment.

Furthermore, although the highly thermally conductive material 19 in the reduced diameter part of the first part 2a is filled, that is, the position shown by the arrow A in the example shown in FIG 7 is shown, the highly thermally conductive material 19 to the second part 2 B of the cylindrical component 2 be filled in, like in 8th is shown.

The rest of the construction is the same as in the first embodiment.

The operation and effect of the present embodiment will be explained below.

In the present embodiment, since the highly heat conductive material 19 between the first part 2a of the cylindrical component 2 and the thermal sensor 3 is filled, the temperature of the measured body and the temperature of the thermosensor 3 just the same size.

Therefore, the response of the temperature sensor 1 be increased to the temperature change of the measured body.

The rest of the operation and the effect are the same as those in the first embodiment.

(Fourth Embodiment)

The present embodiment is an example in which the portion in which the thermal sensor 3 is arranged inside (the first part 2a ), and the section in which the distance between the peripheral surfaces of the insulating tube 4 (the second part 2 B ) of the cylindrical component 2 is formed, uniformly (integrally) are formed, as in 9 is shown.

That is, the cylindrical member 2 is from the first part 2a and the second part 2 B formed as a single component, other than a separate provision of the first part 2a and the second part 2 B and then welding them to the cylindrical member 2 (please refer 2 ), as shown in the first embodiment.

Such a cylindrical component 2 can be made for example by a deep drawing process.

The rest of the removal is the same as in the first embodiment.

The operation and effect of the present embodiment will be explained below.

With the above-mentioned structure, it is difficult to prevent corrosion, etc. in the cylindrical member 2 occurs.

That is, although the first part 2a and the second part 2 B (please refer 2 ) can be formed separately and then welded together, etc., sensitization due to welding (Cr ₂₃ C ₆ is generated at a grain boundary and, for example, a Cr concentration at the grain boundary decreases), whereby the welded portion 250 can easily corrode.

Furthermore, there is a problem that additional heat stress at the time of welding at the welding portion 250 is produced.

However, if the first part 2a and the second part 2 B uniformly (integrally) by performing a deep-drawing process, etc., a welding process is no longer required and thereby it is avoided that the disadvantage of corrosion of the welding section occurs.

The rest of the operation and the effect are the same as those in the first embodiment.

A temperature sensor 1 has a cylindrical component 2 from which an end 21 is closed, a thermal sensor 3 which is in the cylindrical component 2 is arranged, an insulation tube 4 and a pair of signal lines 5 , The insulation pipe 4 made of a sintered ceramic body is in the cylindrical member 2 arranged and has a pair of penetration holes 40 which is the cylindrical component 2 penetrate X in an axial direction. The pair of signal lines 5 is with the thermosensor 3 connected and passes through the penetration hole 40 the insulation tube through. At least in part of a region in the axial direction X of the insulating tube 4 is a distance (gap) 10 between an inner peripheral surface 20 of the cylindrical component 2 and a peripheral surface 45 of the insulation tube 4 educated. A support component 6 that the isolation pipe 4 with the distance 10 supports, between the cylindrical component 2 is formed is in the cylindrical member 2 arranged.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2000-162051 [0002]

Claims (7)

Temperature sensor with: a cylindrical member having an end which is closed; a thermal sensor disposed in the cylindrical member; an insulation tube made of a sintered ceramic body disposed in the cylindrical member having a pair of penetrating holes penetrating through the cylindrical member in the axial direction; and a pair of signal lines connected to the thermal sensor and passing through the penetration hole of the insulation tube, wherein at least a part of a region in the axial direction of the insulating tube, a distance between an inner peripheral surface of the cylindrical member and a peripheral surface of the insulating tube is formed, and a support member which supports the insulation tube at a distance formed between the cylindrical members, is disposed in the cylindrical member. Temperature sensor according to claim 1, wherein the diameter of a portion in which the thermal sensor is arranged from the cylindrical components, is smaller than the diameter of a portion in which the distance is formed. Temperature sensor according to claim 2, wherein the portion in which the temperature sensor is disposed inside, and the portion in which the distance between the peripheral surfaces of the insulating tube of the cylindrical member is arranged uniformly. Temperature sensor according to claim 1, 2 or 3, wherein the support member has a cylinder-side portion, an insulating pipe portion and a connecting portion; the cylinder-side portion fixes the support member to the cylindrical member by urging the inner peripheral side of the cylindrical member outward in a radial direction; the insulating pipe section surrounds the peripheral surface of the insulating pipe; and the connecting portion connects the cylinder-side portion and the insulated, cylinder-side portion. Temperature sensor according to one of claims 1 to 4, wherein the support member is made of a body having an elasticity. A temperature sensor according to claim 1, 2 or 3, wherein the support member is made of a metal mesh in which small caliber metal wires are entangled. Temperature sensor according to one of claims 1 to 6, wherein a highly thermally conductive material whose thermal conductivity is higher than air, between an inner peripheral surface of the cylindrical member and an outer surface of the thermal sensor is filled.

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