DE112015002013T5 - gas sensor - Google Patents

Abstract

A gas sensor is equipped with a housing, an insulator, an inner shell and an outer shell. An inner peripheral hole of the housing is composed of a rear hole portion and a front hole portion, and further has an inclined shoulder at a boundary between the rear hole portion and the front hole portion. The inner shell has a large diameter portion facing the shoulder. The insulator has a flange to hold the large diameter portion between itself and the shoulder. A cylindrical portion of the inner shell and a cylindrical portion of the outer shell are partially joined together by a weld. This weld is shaped to bulge from an outer periphery of the outer shell 52 so that it may contact the front hole portion 211, thereby avoiding overheating of the inner shell and outer shell welds to thermally protect the weld.

Description

TECHNICAL AREA

The invention generally relates to a gas sensor constructed to have a sheath held between a sensor body and an inner peripheral hole of a housing.

BACKGROUND ART

Gas sensors that measure the concentration of oxygen have an inner shell and an outer shell that envelop a portion of a gas sensor device and are disposed between the gas sensor device or a sensor body into which the gas sensor device is inserted and an inner peripheral hole of a housing. Exhaust gas emitted from an internal combustion engine is introduced into a device portion of the gas sensor device through holes formed in the inner shell and the outer shell. The device section functions to measure the concentration of oxygen contained in the exhaust gas.

For example, an oxygen concentration detector disclosed in Japanese Utility Model Second Publication No. 55-17164 has a first protective member and a second protective member having a plurality of holes through which measurement gas is admitted and one portion of an oxygen concentration measuring apparatus Envelop, which is exposed to the measurement gas. The second protective member is disposed within the first protective member with an air gap between it and the first protective member so that the holes thereof are misaligned with those of the first protective member. The oxygen concentration detector is designed to direct the measurement gas whose flow velocity has been decreased to the oxygen concentration measurement device to eliminate the risk of damage to the oxygen concentration measurement device resulting from a sudden change in the temperature of the measurement gas.

SUMMARY OF THE INVENTION

PROBLEM TO BE SOLVED BY THE INVENTION

In the case where the inner shell and the outer shell are welded together, the weld of the inner shell and the outer shell is designed so as not to be exposed to high temperature exhaust gas to prevent the weld from being undesirably heated by the high temperature exhaust gas ,

However, when the weld is enveloped by the housing to protect it from the exhaust, but the exhaust gas is at a very high temperature, the heat may be transferred to the weld by means of thermal conductivity of the inner and outer sheaths. There is therefore still room for improvement in protecting the weld from the high temperature exhaust gas.

The invention has been made in view of the foregoing problems. An object of the invention is to provide a gas sensor which avoids overheating of a weld of an inner shell and an outer shell to protect the weld from heat.

MEDIUM TO SOLVE THE PROBLEM

An embodiment of the invention is a gas sensor comprising a cylindrical housing, a device body inserted into an inner peripheral hole of the housing, the device body itself being a gas sensor device or a member into which the gas sensor device is inserted, and an inner shell and an outer shell that envelops a portion of the gas sensor device and is held between the inner peripheral hole of the housing and the device body. The inner shell is placed inside the outer shell to overlap it.

The inner peripheral hole of the housing has a front hole portion located at a front end side of the device body, a rear hole portion that is closer to a rear end side than the front hole portion and larger in diameter than the front hole portion, and a diameter Shoulder formed between the rear hole portion and the front hole portion in a vertical or oblique shape.

At least one of the inner shell and the outer shell has a cylindrical portion inserted into the front hole portion and a large diameter portion larger in diameter than the cylindrical portion and facing the shoulder.

The device body has a flange projecting from an outer periphery thereof to hold the large-diameter portion between itself and the shoulder.

The cylindrical portion of the inner shell and the cylindrical portion of the outer shell are partially joined together by a weld.

The weld is formed to bulge from an outer periphery of the outer shell so that it can contact the front hole section.

USEFUL EFFECT OF THE INVENTION

In the foregoing gas sensor, the cylindrical portion of the inner shell and the cylindrical portion of the outer shell are joined together by the weld. The weld is formed to have a shape that bulges on the outer periphery of the outer shell so that it can contact the front hole portion of the inner peripheral hole of the housing.

The exhaust gas contacting the outer shell and the inner shell is introduced into the interior of the inner shell. When the gas sensor device measures the concentration of oxygen contained in the exhaust gas, the heat from the outer shell and the inner shell will be transferred to the weld. The weld 6 As described above, which is shaped to bulge from the outer periphery of the outer shell, thus causing the heat that is conducted to the weld to escape from the housing.

The previous gas sensor therefore avoids overheating the weld of the inner shell and outer shell to thermally protect the weld.

BRIEF DESCRIPTION OF THE DRAWINGS

1 FIG. 10 is an explanatory sectional view illustrating a gas sensor according to an embodiment. FIG.

2 Fig. 12 is an explanatory enlarged sectional view illustrating a region around a weld of an inner shell and an outer shell of a gas sensor in an embodiment.

3 Fig. 12 is an explanatory enlarged sectional view illustrating a region around a weld of an inner shell and an outer shell before being installed in a gas sensor in an embodiment.

4 (a) FIG. 10 is a graph indicating a relationship between a distance D between a bending start point at which an inner portion of an inner sheath bends and a rear end surface of an outer sheath and a degree of stress occurring in the inner sheath in an embodiment.

4 (b) FIG. 16 is a graph showing a relationship between a distance CD derived by subtracting the previous distance D from a distance C between a bending start point and the center of a weld in an axial direction, and a degree of strain occurring in the outer shell; represents.

5 Fig. 12 is an explanatory enlarged sectional view illustrating a region around a weld of an inner shell and an outer shell in another gas sensor in an embodiment.

EMBODIMENT FOR CARRYING OUT THE INVENTION

A gas sensor according to an embodiment will be described below.

The above-described weld of the gas sensor is produced by resistance welding (for example, projection welding), laser welding or arc welding. In the case where the cylindrical portion of the inner shell and the cylindrical portion of the outer shell are welded together, the weld may be supplied from a portion of outer shell material or material to portions of the inner and outer shells to be joined will be produced. Such a portion or material supplied melts and bulges on the outer periphery of the outer shell. The portion of the outer shell that will form the weld may be shaped to protrude outwardly from a peripheral portion of the outer shell.

The weld may be made of a plurality of portions distributed at a plurality of locations in the cylindrical portion of the inner shell and the cylindrical portion of the outer shell in a circumferential direction, or may be shaped to extend over an entire circumference of the cylindrical portion of the inner shell and the cylindrical portion of the outer shell to extend.

In this case, the weld in the circumferential direction of the cylindrical portion of the inner shell and the cylindrical portion of the outer shell may be provided as uniformly as possible to ensure stable joining of the inner shell and the outer shell, and so that the heat from the Welding point to the housing adequately escapes.

The front hole portion has the large-diameter portion formed at the site facing the weld and the small-diameter portion closer to the front end side than the large-diameter portion and smaller in diameter as the section of a large diameter is on. The space formed between the cylindrical portion of the outer shell and the small diameter portion is smaller than the space formed between the cylindrical portion of the outer shell and the large diameter portion.

In this case, the likelihood that the heat of a high temperature exhaust gas is transported to the weld is minimized by dissipating the heat from the cylindrical portion of the outer shell to the small diameter portion of the front hole portion of the housing.

The front hole portion has the large-diameter portion formed at the site facing the weld and the small-diameter portion closer to the front end side than the large-diameter portion and smaller in diameter as the section of a large diameter is on. The cylindrical portion of the outer shell has the rear end portion facing the large diameter portion and the front end portion smaller in diameter than the rear end portion and facing the small diameter portion. The outer diameter of the rear end portion is larger than the inner diameter of the small diameter portion.

This allows the rear end portion of the outer shell to be caught by the shoulder formed between the large-diameter portion and the small-diameter portion of the housing when the outer shell falls out of the housing during assembly of the gas sensor, thus a separation of the outer shell is avoided.

In the case where the front hole portion has the large-diameter portion and the small-diameter portion, the outer diameter of the cylindrical portion of the outer shell can be maintained constant.

Embodiment

The gas sensor 1 This embodiment will be described in detail with reference to the drawings.

The gas sensor 1 is how in 1 is shown, with the cylindrical housing 2 , the insulator 4 , the inner shell 51 and the outer shell 52 fitted. The insulator is provided as a device body which fits into an inner peripheral hole 21 (also referred to as an inner chamber) of the housing 2 is introduced, and in the gas sensor device 3 is introduced. The inner and outer sheaths 51 and 52 envelop a portion of the gas sensor device 3 and be between the inner peripheral hole 21 of the housing 2 and the insulator 4 recorded. The inner shell 51 is inside the outer shell 52 placed to overlap with it. The inner peripheral hole 21 of the housing 2 has a front hole section 211 , a rear hole section 212 and a sloping shoulder 213 on. The front hole section 211 located on a front end side of the insulator 4 , The rear hole section 212 is closer to the rear end than the front hole section 211 and is larger in diameter than the front hole portion 211 , The sloping shoulder 213 is located at a boundary of the back hole section 212 and the front hole section 211 ,

The inner shell 51 points as in 2 is shown, a cylindrical portion 511 in the front hole section 211 is introduced, and a section 513 , which is larger in diameter than the cylindrical portion 511 is and the shoulder 213 turned on, on. The insulator 4 has a flange 41 projecting from an outer periphery thereof and the portion 513 a large diameter between itself and the shoulder 213 holds. The cylindrical section 511 the inner shell 51 and the cylindrical section 521 the outer shell 52 are through a weld 6 partially joined together. The weld 6 bulges from the outer periphery of the outer shell 52 so that it is the front hole section 211 can touch.

The gas sensor 1 is explained in more detail below with reference to 1 to 4 described.

The gas sensor 1 is installed in an exhaust pipe of a vehicle and functions to measure a concentration of oxygen in an exhaust gas emitted through the exhaust pipe. The inner shell 51 and the outer shell 52 of the gas sensor 1 are located inside the exhaust pipe. In the inner shell 51 and the outer shell 52 are how it is in 1 is shown, through holes 515 and 525 formed, through which the exhaust gas is admitted as a measurement gas to a measuring section 31 the gas sensor device 3 to reach within the inner shell 51 is arranged. The inner shell 51 is inside the outer shell 52 arranged and overlapped with it. The locations of the through holes 525 the outer shell 52 differ in an axial direction L from those of the through holes 515 the inner shell 51 ,

The axial direction L referred to herein is a direction in which the inner peripheral hole 21 of the housing 2 is formed. The central axis is an imaginary line passing through the center of the inner peripheral hole 21 of the housing 2 goes. The front end side is a region where the inner shell 51 and the outer shell 52 from the case 2 project or the measuring section 31 the gas sensor device 3 from the insulator 4 protrudes. The rear end side is on the opposite side of the front end side.

The cylindrical section 511 the inner shell 51 and the cylindrical section 521 the outer shell 52 as it is clear in 1 is shown, have in the axial direction L rear end portions which face each other. The cylindrical section 511 the inner shell 51 has a front end portion in the axial direction L, the diameter of which decreases inwardly, and at a given interval away from a front end portion of the cylindrical portion 521 the outer shell 52 located. The inner shell 51 and the outer shell 52 have a cylindrical shape with a bottom and have the cylindrical sections 511 and 521 and floors 512 and 522 , respectively through front ends of the cylindrical sections 511 and 521 are defined on. The through holes 515 and 525 are in the cylindrical sections 511 and 521 and the floors 512 and 522 educated.

The front hole section 211 of the housing 2 as it is in 2 is shown has a section 211A of a large diameter, in one place, of the weld 6 facing, is formed, and a section 211B a small diameter that is closer to the front end than the section 211A is of a large diameter and has a diameter smaller than that of the section 211A a large diameter is on. A gap S2 between a front end portion 521B of the cylindrical section 521 the outer shell 52 in the axial direction L and the section 211B a small diameter is smaller than a clearance S1 between a rear end portion 521A of the cylindrical section 521 the outer shell 52 in the axial direction L and the section 211A a large diameter. One shoulder 211C is between the section 211A a large diameter and the section 211B a small diameter formed.

A rear end section 511A of the cylindrical section 511 the inner shell 51 in the axial direction L and the rear end portion 521A of the cylindrical section 521 the outer shell 52 in the axial direction L are contoured to conform to a stepped shape as through the section 211A a large diameter and the section 211B of a small diameter, and have diameters each larger than those of a front end portion 511B of the cylindrical section 511 the inner shell 51 in the axial direction and the front end portion 521B of the cylindrical section 521 the outer shell 52 in the axial direction L are. The rear end section 521A the outer shell 52 is the section 211A of a large diameter, while the front end portion 521B the outer shell 52 the section 211B facing a small diameter.

An outer diameter φA of the rear end portion 521A the outer shell 52 is larger than an inner diameter φB of the section 211B a small diameter of the housing 2 , This allows the rear end section 521A the outer shell 52 through the shoulder 211C that between the section 211A a large diameter and the section 211B a small diameter of the housing 2 is formed, is absorbed when the outer shell 52 during assembly of the gas sensor 1 out of the case 2 falls, causing a detachment of the outer shell 52 is avoided.

The section 513 of a large diameter of this embodiment is at the rear end of the cylindrical portion 511 the inner shell 51 formed in an oblique shape to have a diameter that increases as approached to the rear end side. The section 513 of a large diameter is formed as a flange portion of the cylindrical portion 511 which is parallel to the axial direction L, is bent to be oblique.

The inner shell 51 may alternatively be shaped to the section 513 not to have a large diameter. The outer shell 52 can instead the section 513 have a large diameter. The gas sensor 1 can be shaped to take the place of a double-shell structure, which consists of the inner shell 51 and the outer shell 52 is constructed to have a single shell structure. In this case, the single-hull structure may have a section 513 of a large diameter formed at a rear end portion thereof.

The weld 6 , in the 2 is shown is the section 211A a large diameter of the front hole section 211 of the housing 2 facing and extending in the circumferential direction completely over the entire peripheries of the cylindrical portion 511 the inner shell 51 and the cylindrical portion 521 the outer shell 52 from that. The circumferential direction referred to herein is a direction about the central axis of the inner shell 51 and the outer shell 52 which extends parallel to the axial direction L. The weld 6 is in a location that is the section 211A a large diameter of the front hole section 211 of the housing 2 is facing. The weld 6 is through a section of material of the outer shell 52 which is melted and then outside the outer periphery of the outer shell 52 spreads, formed when the cylindrical section 511 the inner shell 51 and the cylindrical section 521 the outer shell 52 be welded together. The track with which the weld 6 from the cylindrical section 521 the outer shell 52 protrudes, may be 0.05 mm or more.

The weld 6 can be over the shoulder between the rear end section 511A and the front end portion 511B the inner shell 51 is formed, and the shoulder between the rear end portion 521A and the front end portion 521B the outer shell 52 is formed, extend.

The insulator 4 as he is in 1 is shown, has a through hole 42 , which is formed in the middle of the same. The gas sensor device 3 is in the through hole 42 introduced. The measuring section 31 the gas sensor device 3 Working to measure the concentration of oxygen is available from the isolator 4 in the axial direction L toward the front end side. A flange 41 of the insulator 4 protrudes and is shaped to have an increasing diameter of a whole circumference thereof. The flange 41 has a front end surface 411 with the same angle as the same with which the section 513 a large diameter is inclined, inclined.

In the front hole section 211 of the inner peripheral hole 21 of the housing 2 are a rear end portion of the cylindrical portion 511 the inner shell 51 in the axial direction L and a rear end portion of the cylindrical portion 521 the outer shell 52 fitted in the axial direction L. The shoulder 213 of the housing 2 has an end surface that has an oblique shape and has a diameter that increases as it approaches the rear end side.

A distance D between a bending start point P1, at which an inner portion of the section 513 a large diameter of the cylindrical portion 511 the inner shell 51 is bent, and a rear end surface 526 the outer shell 52 is preferably selected to have a relationship of D> 2t, where t is the thickness of the inner shell 51 is. 4 (a) is a graph showing a relationship between the distance D and a degree of stress in the inner shell 51 occurs, indicates. The graph shows that the voltage level decreases as the distance D increases. This tension acts between the rear end of the outer shell 52 and the bending start point. The relationship D> 2t serves to determine the degree of stress in the inner shell 51 is generated to reduce.

The weld 6 is preferably further away from the bending start point described above. A distance CD obtained by subtracting the distance D from a distance C between the previous bending start point P1 and the center P2 of the weld 6 is derived in the axial direction L, preferably satisfies a relationship CD> 4t. 4 (b) is a graphic representation showing a relationship between the CD distance and a degree of elongation in the outer shell 52 occurs, represents. The graph shows that a greater degree of elongation in the outer shell 52 appears in an area where the distance CD is less than 4t. The strain results from a heat of welding, that of the weld 6 to the outer shell 52 is transmitted. An increase in tension will cause the outer shell 52 is deformed outwardly in the radial direction thereof. The relationship CD> 4t serves to deform the outer shell 52 desired to minimize.

Like the gas sensor 1 and the operation and useful advantages of the gas sensor 1 are described below.

Before assembling the gas sensor 1 becomes the cylindrical section 511 the inner shell 51 , as in 3 is shown within the cylindrical portion 521 the outer shell 52 placed to overlap each other. The cylindrical section 511 and the cylindrical section 521 are then welded together. This causes a weld 6 is formed, which is in the shape of a convex body on the outer periphery of the cylindrical portion 521 the outer shell 52 bulges. The inner shell 51 and the outer shell 52 are thus joined together.

When assembling the gas sensor 1 will be the inner shell next 51 and the outer shell 52 , as in 1 and 2 is shown in the inner peripheral hole 21 of the housing 2 introduced. The insulator 4 gets into the inner shell 51 introduced. The cylindrical section 511 the inner shell 51 becomes in the inner peripheral hole 21 of the housing 2 arranged. The section 513 a large diameter of the inner shell 51 is the shoulder 213 of the inner peripheral hole 21 of the housing 2 facing. The end surface 411 of the flange 41 of the insulator 4 is the rear end surface of the section 513 a large diameter of the inner shell 51 facing.

After the inner shell 51 , the outer shell 52 and the insulator 4 into the inner peripheral hole 21 of the housing 2 introduced, becomes an insulating powder 23 , such as talc, into a gap between the rear hole section 212 of the inner peripheral hole 21 of the housing 2 and the outer periphery of the insulator 4 brought. A porcelain insulator 24 is on the back end of the insulating powder 23 between the rear hole section 212 and the outer periphery of the insulator 4 arranged. The section 22 the rear end of the housing 2 is folded towards the front end side to the insulating powder 23 and the porcelain insulator 24 between the rear end surface 412 of the flange 41 of the insulator 4 and the folded section 22 to keep the section 513 a large diameter between the shoulder 213 of the housing 2 and the front end surface 411 of the flange 41 of the insulator 4 is stably held.

After the gas sensor 1 assembled, is the weld 6 in the cylindrical section 521 the outer shell 5 is formed, the section 211A a large diameter of the front hole section 211 of the inner peripheral hole 21 of the housing 2 facing. The weld 6 is formed to have a shape that rests on the outer periphery of the outer shell 52 arch, so that same section 211A of a large diameter can touch.

When using the gas sensor 1 becomes the exhaust that is with the outer shell 52 and the inner shell 51 into the inner shell 51 initiated. When the gas sensor device 3 The concentration of oxygen contained in the exhaust gas becomes the heat from the outer shell 52 and the inner shell 51 to the weld 6 transfer. The weld 6 As described above, it is shaped to protrude from the outer periphery of the outer shell 52 to buckle, so that causes the heat leading to the weld 6 is directed to the housing 2 escapes.

The gap S2 between the front end portion 521B the outer shell 52 and the section 211B a small diameter of the inner peripheral hole 21 of the housing 2 is smaller in clearance than the clearance S1 between the rear end portion 521A the outer shell 52 and the section 211A a large diameter of the inner peripheral hole 21 of the housing 2 , This promotes a lightness with the heat that passes from the high temperature exhaust gas to the outer shell 52 is guided by the cylindrical section 521 the outer shell 52 to the section 211B a small diameter of the front hole section 211 of the housing 2 escapes, thereby reducing the degree to which the heat of the high temperature exhaust to the weld 6 is transmitted.

The gas sensor 1 avoids accordingly the overheating of the weld 6 the inner shell 51 and the outer shell 52 to thereby the weld 6 to protect thermally.

The weld 6 is shaped to stand out from the outer periphery of the outer shell 52 to arch, so that same section 211A a large diameter of the front hole section 211 of the inner peripheral hole 21 of the housing 2 can touch, causing misalignment of the center axis of the inner shell 51 and outer shell 52 with the center axis of the inner peripheral hole 21 of the housing 2 is avoided. This prevents the section 513 a large diameter of the inner shell 51 undesirable the insulator 4 bothers when the gas sensor 1 and eliminates the risk of damage or breakage of the insulator 4 ,

The device body is out of the insulator 4 Alternatively, however, it may be made of a solid electrolyte body constituting the gas sensor device. The solid electrolyte body has a cylindrical shape with a bottom and has a flange similar in configuration to that of the flange 41 of the insulator 4 is. The solid electrolyte body has a pair of electrodes fixed to an inner and an outer peripheral surface thereof for measuring the concentration of oxygen in the exhaust gas.

Both the cylindrical section 511 the inner shell 51 as well as the cylindrical section 521 the outer shell 52 can, as in 5 is shown to be shaped to have a constant outer diameter. This structure causes a weld 6 coming from the outer periphery of the cylindrical section 521 the outer shell 52 protrudes, on the shoulder 211C of the housing 2 is caught when the outer shell 52 undesirable from the housing 2 falls when the gas sensor 1 assembled, thereby increasing the risk of detachment of the outer shell 52 is eliminated.

Claims (4)

Gas sensor ( 1 ) with: a cylindrical housing ( 2 ); a device body ( 4 ) located in an inner peripheral hole ( 21 ) of the housing ( 2 ), the device body itself being a gas sensor device ( 3 ) or a member into which the gas sensor device ( 3 ) is introduced; and an inner shell ( 51 ) and an outer shell ( 52 ) comprising a portion of the gas sensor device ( 3 ) and between the inner peripheral hole ( 21 ) of the housing ( 2 ) and the device body ( 4 ), wherein the inner shell is placed within the outer shell so as to overlap therewith, characterized in that the inner peripheral hole (11) 21 ) of the housing ( 2 ) a front hole section ( 211 ) located on a front end side of the device body ( 4 ), a rear hole section ( 212 ), which is closer to a rear end side than the front hole section (FIG. 211 ) and larger in diameter than the front hole section (FIG. 211 ), and a shoulder ( 213 ), which between the rear hole section ( 212 ) and the front hole section ( 211 ) is formed in a vertical or oblique shape, at least either the inner shell ( 51 ) or the outer shell ( 52 ) a cylindrical section ( 511 . 521 ), which is in the front hole section ( 211 ), and a section ( 513 ) of a large diameter larger in diameter than the cylindrical portion ( 511 . 521 ) and the shoulder ( 213 ), the device body ( 4 ) a flange ( 41 ) protruding from an outer circumference thereof, around the portion (FIG. 513 ) of a large diameter between itself and the shoulder ( 213 ), the cylindrical section ( 511 ) of the inner shell ( 51 ) and the cylindrical section ( 521 ) of the outer shell ( 52 ) through a weld ( 6 ) are partially joined together, and the weld ( 6 ) is formed to extend from an outer periphery of the outer shell ( 52 ) so that it covers the front hole section ( 211 ) can touch. Gas sensor ( 1 ) according to claim 1, characterized in that the weld ( 6 ) of a plurality of portions arranged in a circumferential direction at a plurality of locations in the cylindrical portion (FIG. 511 ) of the inner shell ( 51 ) and the cylindrical section ( 521 ) of the outer shell ( 52 ), is constructed or shaped to extend over an entire circumference of the cylindrical portion ( 511 ) of the inner shell ( 51 ) and the cylindrical portion ( 521 ) of the outer shell ( 52 ). Gas sensor ( 1 ) according to claim 1 or 2, characterized in that the front hole section ( 211 ) a section ( 211A ) of a large diameter, at a location close to the weld ( 6 ) is formed, and a section ( 211B ) of a small diameter, which is closer to a front end side than the section ( 211A ) of a large diameter and smaller in diameter than the section ( 211A ) of a large diameter, and wherein a gap (S2) between the cylindrical portion ( 521 ) of the outer shell ( 52 ) and the section ( 211B ) of a small diameter is smaller than a gap (S1) between the cylindrical portion ( 521 ) of the outer shell ( 52 ) and the section ( 211A ) is formed of a large diameter. Gas sensor ( 1 ) according to claim 1 or 2, characterized in that the front hole section ( 211 ) a section ( 211A ) of a large diameter, at a location close to the weld ( 6 ) is formed, and a section ( 211B ) of a small diameter, which is closer to a front end side than the section ( 211A ) of a large diameter and with respect to the diameter smaller than the section ( 211A ) of a large diameter, wherein the cylindrical portion ( 521 ) of the outer shell ( 52 ) a rear end portion ( 521A ), the section ( 211A ) faces a large diameter, and a front end portion ( 521B ), which is smaller in diameter than the rear end portion ( 521A ) and the section ( 211B ) of a small diameter, and wherein an outer diameter (φA) of the rear end portion ( 521A ) greater than an inner diameter (φB) of the section ( 211B ) of a small diameter.

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