BACKGROUND OF THE INVENTION
1. Field of the Invention
[0001] The present invention relates to a glow plug.
2. Description of the Related Art
[0002] A glow plug typically includes a heater, which is a heating element, at a front-end
portion in an axial direction. A sheath heater is known as one of such heaters. The
sheath heater includes a cylindrical sheath tube whose front-end portion is closed
and a heating coil that is located in the sheath tube and that generates heat as a
result of transmission of electricity. In such a sheath heater, the front-end portion
of the heating coil is welded to the front-end portion of the sheath tube.
[0003] It has been known that a coil composed of, for example, an Fe-Cr-Al alloy is used
for the heating coil. In the glow plug, the temperature of the heating coil becomes
1000°C or more during heating by the heater. At this time, there is a possibility
that the heating coil melts and becomes disconnected when the temperature of the heating
coil locally increases excessively. For this reason, the heating coil is formed of
a metal having a higher melting point to inhibit the coil from becoming disconnected
due to the melt of the heating coil and to improve the durability of the glow plug.
Specifically, a glow plug including a heating coil whose main component is tungsten
(W) or molybdenum (Mo), which is a metal having a high melting point is proposed (for
example, see PTL 1 to PTL 4).
[0004] DE 10 2013 212 283 A1 discloses a glow plug having a heater with a sheet tube and a heating coil contained
in this sheet tube. In particular, in Dl, the respective heating coil may contain
lanthanum oxide, thorium dioxide, and/or cerium dioxide, and/or yttrium dioxide in
addition to molybdenum and tungsten.
Citation List
Patent Literature
[0006]
PTL 1: Japanese Unexamined Patent Application Publication No. 2015-099008
PTL 2: Japanese Unexamined Patent Application Publication No. 2015-078784
PTL 3: International Publication No. 2011/162074
PTL 4: Japanese Unexamined Patent Application Publication No. 11-237045
SUMMARY OF THE INVENTION
[0007] However, in the case where the heating coil is composed of tungsten (W) or molybdenum
(Mo), a metal, such as nickel (Ni) or iron (Fe), forming the sheath tube diffuses
into the heating coil at a joint between the heating coil and the sheath tube during
heating by the heater. At the location of the heating coil where the metal of which
the sheath tube is composed diffuses, the melting point of the metal of which the
heating coil is composed decreases, disconnection is likely to occur, and there is
a possibility that the heat resistance of the heating coil decreases. In the case
where the diffusion progresses, for example, there is a possibility that the melting
point of the heating coil, which exhibits a melting point of about 3000°C, locally
decreases to less than 1500°C. The diffusion of the metal of which the sheath tube
is composed into the heating coil progresses mainly at a crystal grain boundary of
the metal of which the heating coil is composed. Accordingly, the diffusion leads
to grain boundary embrittlement in the heating coil. Consequently, the heating coil
is likely to become disconnected at the location where the grain boundary embrittlement
progresses when a stress is applied thereto, and there is a possibility that the durability
of the heater and the glow plug further decreases.
[0008] The present invention has been accomplished to solve the above problems and can be
achieved as the following aspects.
- (1) According to an aspect of the present invention, a glow plug includes a heater
including a tubular sheath tube that extends in an axial direction and that has a
closed front end, a heating coil accommodated in the sheath tube with a front-end
portion thereof joined to a front-end portion of the sheath tube, and an insulator
filled in the sheath tube around the heating coil. In the glow plug, the heating coil
contains at least one selected from tungsten (W) and molybdenum (Mo) as a main component
and contains an additional element that is at least one element selected from potassium
(K), aluminum (Al), silicon (Si), lanthanum (La), thorium (Th), and cerium (Ce). The
sheath tube contains at least one metal selected from nickel (Ni) and iron (Fe). A
melt portion that is in contact with an outer surface of the front-end portion of
the heating coil and that contains at least the same material as that of a portion
of the sheath tube other than the melt portion is formed at the front-end portion
of the sheath tube. When a cross section of a wire forming the heating coil is viewed
at the front-end portion of the heating coil, the additional element exists at a crystal
grain boundary of the main component at least in a surface layer extending from the
outer surface of the heating coil to a length of a quarter of a diameter of the wire.
In the front-end portion of the heating coil of the glow plug according to the aspect,
the additional element exists at the crystal grain boundary of the main component
of which the heating coil is composed at least in the surface layer extending from
the outer surface of the heating coil to a length of a quarter of the diameter of
the wire. Accordingly, during heating by the heater, at least one metal selected from
nickel (Ni) and iron (Fe) and contained in the melt portion can be inhibited from
diffusing from the melt portion into the heating coil along the crystal grain boundary
of the main component of which the heating coil is composed. Consequently, the durability
of the heater and the glow plug can be inhibited from decreasing due to diffusion
of the metal of which the sheath tube is composed into the heating coil. In addition,
the grain boundary embrittlement in the heating coil is inhibited from progressing,
and the durability of the heater and the glow plug can be inhibited from decreasing.
It is only necessary for the additional element to exist at the crystal grain boundary
of the main component of which the heating coil is composed at least in the surface
layer. The additional element may exist at the crystal grain boundary of the main
component over the entire heating coil.
- (2) In the glow plug according to the above aspect, the additional element may exist
as an oxide at the crystal grain boundary. In the glow plug according to this aspect,
the additional element that exists as an oxide is more stable than in the case where
the additional element exists as a metal, and accordingly, the stability of the effect
of inhibiting metal diffusion from the melt portion into the heating coil can be improved.
- (3) In the glow plug according to the above aspect, a content of the additional element
of the heating coil is 5 ppm or more. In the glow plug according to this aspect, since
the content of the additional element of the heating coil is 5 ppm more, the additional
element can easily exist at the crystal grain boundary of the main component of which
the heating coil is composed at least in the surface layer.
- (4) In the glow plug according to the above aspect, a content of the additional element
of the heating coil is 200 ppm or less. In the glow plug according to this aspect,
the additional element contained in the heating coil and the insulator filled around
the heating coil are inhibited from reacting with each other, and the heating coil
and the insulator can be inhibited from excessively adhering to each other. Accordingly,
the heating coil can be inhibited from being damaged due to a difference in thermal
expansion coefficient between the heating coil and the insulator.
- (5) In the glow plug according to the above aspect, the heating coil may be joined
to the sheath tube with the front-end portion of the heating coil embedded in the
melt portion. In the glow plug according to this aspect, metal diffusion from the
melt portion into the heating coil can be inhibited at the portion of the heating
coil embedded in the melt portion.
- (6) In the glow plug according to the above aspect, the sheath tube may include a
tubular extension extending in the axial direction and a lid portion that is joined
to the extension at a front-end portion of the extension and that closes the front-end
portion of the sheath tube. The lid portion may include a protrusion protruding to
an inside of the sheath tube. The heating coil may be joined to the protrusion with
the front-end portion of the heating coil wound around the protrusion. In the glow
plug according to this aspect, metal diffusion from the melt portion, which is formed
in the protrusion included in the lid portion of the sheath tube, into the heating
coil can be inhibited.
[0009] The present invention can be achieved as various aspects other than the above aspects.
For example, the present invention can be achieved as aspects of a method of manufacturing
the glow plug, a heater for the glow plug, and a method of manufacturing the heater
for the glow plug.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010]
Fig. 1 is an explanatory view of a schematic structure of a glow plug.
Fig. 2 is an explanatory view of the structure of a sheath heater.
Fig. 3 is an enlarged schematic sectional view of the structure of a front-end portion
of the sheath heater.
Fig. 4 is a flow chart illustrating a method of manufacturing the glow plug.
Figs. 5A and 5B illustrate a welding process.
Fig. 6 is an enlarged schematic sectional view of the structure of the front-end portion
of the sheath heater.
Fig. 7 is an enlarged explanatory view of the structure of the front-end portion of
the sheath heater.
Fig. 8 is an enlarged explanatory view of the structure of the front-end portion of
the sheath heater.
Fig. 9 illustrates a summary of evaluation results of samples.
Fig. 10 illustrates a summary of evaluation results of samples.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
A. First Embodiment
(A-1) Entire Structure of Glow Plug
[0011] Fig. 1 is an explanatory view of a glow plug 10 according to a first embodiment of
the present invention. The glow plug 10 according to the first embodiment functions
as a heat source that assists ignition, for example, when internal combustion engines
including a diesel engine start. As illustrated in Fig. 1, the glow plug 10 includes
a sheath heater 800 that generates heat as a result of transmission of electricity,
a metal shell 500, and a center rod 200 as main components. In Fig. 1, the exterior
structure of the glow plug 10 is illustrated on the right-hand side of an axial line
0 of the glow plug 10, and the sectional structure thereof is illustrated on the left-hand
side of the axial line 0. In the description, the side of the sheath heater 800 in
an axial direction OD parallel to the axial line 0 of the glow plug 10 is referred
to as a "front-end side", and the side of the center rod 200 in the axial direction
OD is referred to as a "rear-end side".
[0012] The metal shell 500 is a member obtained by forming a metallic material such as carbon
steel into a tubular shape. The metal shell 500 holds the sheath heater 800 at the
end portion thereof on the front-end side. The metal shell 500 holds the center rod
200 at the end portion thereof on the rear-end side with an insulating member 410
and an O-ring 460 interposed therebetween. The position of the insulating member 410
in the direction of the axial line O is fixed in a manner in which a ring 300 in contact
with the rear end of the insulating member 410 is crimped along with the center rod
200. The insulating member 410 electrically insulates the metal shell 500 and the
center rod 200 from each other. The metal shell 500 accommodates a portion of the
center rod 200 extending from the insulating member 410 to the sheath heater 800.
The metal shell 500 includes a tool engagement portion 520 and an external thread
portion 540. An axial hole 510 is formed inside the metal shell 500.
[0013] The axial hole 510 is a through-hole formed along the axial line O and has a diameter
larger than the diameter of the center rod 200. A gap for electrically insulating
the periphery of the axial hole 510 and the center rod 200 from each other is formed
between the periphery of the axial hole 510 and the center rod 200 with the position
of the center rod 200 with respect to the axial hole 510 set. The sheath heater 800
is press-fitted in and joined to the axial hole 510 on the front-end side. The external
thread portion 540 is to be screwed into an internal thread formed on an internal
combustion engine (not illustrated) and attached thereto. The tool engagement portion
520 is to engage a tool (not illustrated) used to attach and detach the glow plug
10.
[0014] The center rod 200 is a member obtained by forming a conductive material into a cylindrical
shape (rod shape). The center rod 200 is assembled along the axial line O with the
center rod 200 inserted in the axial hole 510 of the metal shell 500. A center rod
front-end portion 210, which is a front-end portion of the center rod 200, is inserted
in the sheath heater 800. An external thread portion 290 is formed at the rear end
of the center rod 200. The external thread portion 290 protrudes from the metal shell
500 on the rear-end side and is fitted in an engagement member 100.
(A-2) Structure of Sheath Heater
[0015] Fig. 2 is an explanatory view of the detailed structure of the sheath heater 800.
The sheath heater 800 includes a sheath tube 810, a heating coil 820 serving as a
heating element, a control coil 830, and an insulator 870. In Fig. 2, components other
than the heating coil 820, the control coil 830, and the center rod 200 are illustrated
by their section.
[0016] The sheath tube 810 is a tubular member that extends in the axial direction OD and
has a closed front end. Inside the sheath tube 810, the heating coil 820, the control
coil 830, and the insulator 870 are accommodated. The sheath tube 810 includes a side
surface portion 814, a sheath tube front-end portion 813, and a sheath tube rear-end
portion 819. The side surface portion 814 is a portion that extends in the axial direction
OD and that is formed such that the outer diameter of the cross section (section perpendicular
to the axial line O) is constant over the entire length in the axial direction OD.
The sheath tube front-end portion 813 is a portion that is formed on the front-end
side of the side surface portion 814 such that the diameter gradually decreases and
the sheath tube front-end portion 813 is rounded toward the outside. The sheath tube
rear-end portion 819 is an opened end portion on the rear-end side of the sheath tube
810. The center rod front-end portion 210 is inserted in the sheath tube 810 from
the sheath tube rear-end portion 819. The sheath tube 810 is electrically insulated
from the center rod 200 by using a packing 600 and the insulator 870. The packing
600 is an insulating member interposed between the center rod 200 and the sheath tube
810. The sheath tube 810 is electrically connected to the metal shell 500 in a manner
in which the outer surface thereof is in contact with the metal shell 500.
[0017] The sheath tube 810 contains at least one metal selected from nickel (Ni) and iron
(Fe). More specifically, the sheath tube 810 may be composed of a metallic material
containing nickel (Ni) or iron (Fe) as a main component. For example, the sheath tube
810 may be composed of a nickel-based alloy such as inconel 601 ("inconel" is a registered
trademark) or Alloy 602, or stainless steel such as SUS310S.
[0018] The heating coil 820 is a spiral coil formed of a conductive material. The heating
coil 820 is located inside the sheath tube 810 so as to extend in the axial direction
OD and generates heat as a result of transmission of electricity. The heating coil
820 includes a coil front-end portion 822, which is the end portion on the front-end
side, a spiral portion 823 spirally wound, and a heating coil rear-end portion 829,
which is the end portion on the rear-end side. The heating coil 820 is electrically
connected to the sheath tube 810 in a manner in which the coil front-end portion 822
is welded to the sheath tube 810.
[0019] The heating coil 820 contains at least one selected from tungsten (W) and molybdenum
(Mo) as a main component. The phrase "to contain at least one selected from tungsten
(W) and molybdenum (Mo) as a main component" means that the content percentage (mass%)
of at least one selected from tungsten (W) and molybdenum (Mo) is 50 mass% or more.
With this structure, the melting point of the metal of which the heating coil 820
is composed can be increased, and the durability of the heating coil 820 can be improved.
In addition, the resistance of the heating coil 820 at a high temperature can be decreased,
and the amount of current flowing therethrough can be ensured. The main component
of the heating coil 820 is preferably tungsten (W). The content percentage of the
main component of the heating coil 820 is preferably 80 mass% or more, more preferably
90 mass% or more, further preferably 99 mass% or more. In the case where at least
one selected from tungsten (W) and molybdenum (Mo) is the main component as above,
the melting point of the heating coil 820 can be increased.
[0020] The heating coil 820 contains additional elements, each of which is at least one
element selected from potassium (K), aluminum (Al), silicon (Si), lanthanum (La),
thorium (Th), and cerium (Ce), in addition to the main component. According to the
first embodiment, the additional elements exist at the crystal grain boundary of the
main component at least in a surface layer including at least the outer surface of
the coil front-end portion 822. The additional elements that exist in the coil front-end
portion 822 will be described in detail later.
[0021] The control coil 830 is located on the rear-end side of the heating coil 820 and
formed of a conductive material having a larger temperature coefficient of electrical
resistivity than the temperature coefficient of the material of which the heating
coil 820 is formed. Specifically, the control coil 830 can be formed of, for example,
a nickel-based alloy such as a nickel (Ni)-chrome (Cr) alloy or an iron (Fe)-chrome(Cr)-aluminum
(Al) alloy. The control coil 830 formed of such a material controls power supplied
to the heating coil 820. The control coil 830 includes a control coil front-end portion
831, which is the end portion on the front-end side, and a control coil rear-end portion
839, which is the end portion on the rear-end side. The control coil front-end portion
831 is welded to the heating coil rear-end portion 829 of the heating coil 820 and
is thereby electrically connected to the heating coil 820. The control coil rear-end
portion 839 is joined to the center rod front-end portion 210 of the center rod 200
and is thereby electrically connected to the center rod 200.
[0022] The insulator 870 is formed of powder of an electrically insulating material. Examples
of the powder of the insulating material of which the insulator 870 is composed include
powder of a magnesium oxide (MgO). The insulator 870 is filled inside the sheath tube
810 and electrically insulates the sheath tube 810, the heating coil 820, the control
coil 830, and the center rod 200 from each other in spaces therebetween.
(A-3) Structure of Front-End Portion of Sheath Heater
[0023] Fig. 3 is an enlarged schematic sectional view of the structure of the front-end
portion of the sheath heater 800. The section in Fig. 3 is the section of the sheath
heater 800 cut along a line crossing the axial line O, and the spiral portion 823
and coil front-end portion 822 of the heating coil 820, the sheath tube 810, and the
insulator 870 are illustrated. According to the first embodiment, the central axis
of the sheath heater 800 coincides with the axial line O of the glow plug 10.
[0024] According to the first embodiment, the coil front-end portion 822 is formed on the
axial line O so as to extend linearly along the axial line O. According to the first
embodiment, a melt portion 816 is formed at the sheath tube front-end portion 813.
The melt portion 816 is in contact with the outer surface of the coil front-end portion
822. The composition of the melt portion 816 is the same as a portion of the sheath
tube 810 other than the melt portion 816. Specifically, the melt portion 816 is a
portion whose composition has been changed when the heating coil 820 has been welded
to the sheath tube 810 and the front-end portion of the sheath tube 810 has melted
once. According to the first embodiment, during welding, the heating coil 820 having
a higher melting point does not substantially melt, and only a tubular member, which
will be the sheath tube 810, melts. Accordingly, as illustrated in Fig. 3, the coil
front-end portion 822 is surrounded by and embedded in the melt portion 816.
[0025] According to the first embodiment, the additional elements exist at the crystal grain
boundary of the main component of which the heating coil 820 is composed at least
in a surface layer 825 including at least the outer surface of the coil front-end
portion 822 (specifically, the surface layer including the outer surface in contact
with the melt portion 816), as described above. Each additional element is at least
one element selected from potassium (K), aluminum (Al), silicon (Si), lanthanum (La),
thorium (Th), and cerium (Ce), as described above. In the case where the additional
elements thus exist at the crystal grain boundary of the main component of which the
heating coil 820 is composed, the metal of which the sheath tube 810 is composed can
be inhibited from diffusing into the heating coil 820 from the melt portion 816 via
the crystal grain boundary. The elements of which the sheath tube 810 is composed
diffuse at the coil front-end portion 822 via the crystal grain boundary faster than
when the elements pass through the inside of a crystal grain. Accordingly, in the
case where the additional elements exist at the crystal grain boundary, the metal
of which the sheath tube 810 is composed can be inhibited from diffusing into the
heating coil 820.
[0026] The cross section of a wire forming the heating coil 820 is a section perpendicular
to the direction in which the wire forming the heating coil 820 extends. According
to the first embodiment, the cross section of the wire forming the heating coil 820
is substantially circular, and the cross section of the coil front-end portion 822
extending in the axial direction OD is substantially constant. According to the first
embodiment, the surface layer 825 extends from the outer circumference of a side edge
surface toward the center of the cross section up to a distance R (R=1/4D), where
D represents the diameter of the cross section. Thus, when the cross section of the
wire at the coil front-end portion 822 is viewed, the additional elements exist at
the crystal grain boundary of the main component of which the heating coil 820 is
composed in the surface layer 825. In the case where the cross section of the wire
forming the heating coil 820 is not circular, the diameter D of the cross section
corresponds to the length of the longest line segment of line segments, each of which
passes through the center of gravity of the cross section and has endpoints that are
on the outer circumference of the cross section.
[0027] The content of the additional elements of the heating coil 820 is 5 ppm or more so
that the additional elements thus exist at the crystal grain boundary of the main
component in the surface layer 825. In this way, it is easy for the additional elements
to exist at the crystal grain boundary of the main component of which the heating
coil 820 is composed at least in the surface layer 825 of the coil front-end portion
822 of the heating coil 820. In the case where the additional elements thus exist
at the crystal grain boundary, the content of the additional elements of the heating
coil 820 is preferably 10 ppm or more, more preferably 30 ppm or more, further preferably
50 ppm or more, from the viewpoint of an improvement in the effect of inhibiting metal
diffusion into the heating coil 820.
[0028] The content of the additional elements of the heating coil 820 is 200 ppm or less.
In the glow plug 10 according to the first embodiment, the insulator 870, for example,
powder of a magnesium oxide (MgO), is filled in the space between the heating coil
820 and the sheath tube 810, as described above. In the case where the heating coil
820 of the glow plug 10 contains the additional elements, the additional elements
and MgO can react with each other in the sheath tube 810. The reaction between the
additional elements and MgO increases adhesion between the heating coil 820 and the
insulator 870. Accordingly, when the content of the additional elements of the heating
coil 820 is, for example, more than 200 ppm, the content of the additional elements
is excessive, and there is a possibility that the heating coil 820 and the insulator
870 excessively adhere to each other. The thermal expansion coefficient of tungsten
(W) or molybdenum (Mo) of which the heating coil 820 is composed is lower than the
thermal expansion coefficient of MgO. Accordingly, there is a possibility that during
heating by the sheath heater 800, a large stress due to a difference in the thermal
expansion coefficient is produced at a location at which the additional elements and
MgO react with each other and the adhesion between the heating coil 820 and the insulator
870 is increased. At such a location at which a large stress is produced, the heating
coil 820 is likely to become disconnected. Accordingly, the content of the additional
elements of the heating coil 820 is preferably 180 ppm or less, more preferably 150
ppm or less, further preferably 120 ppm or less, from the viewpoint of an improvement
in the effect of inhibiting the heating coil 820 from becoming disconnected due to
the reaction between the additional elements and MgO and the effect of inhibiting
the durability of the glow plug 10 from decreasing due to the disconnection.
[0029] When the heating coil 820 is manufactured, the additional elements may be added to
and mixed with the material of the heating coil 820 in advance so that the heating
coil 820 contains the additional elements. In the case where several kinds of additional
elements are used, the content of the additional elements means the total content
of the several kinds of additional elements.
[0030] In order to identify whether the additional elements exist at the crystal grain boundary
of the main component of which the heating coil 820 is composed in the surface layer
825 of the heating coil 820, the cross section of the coil front-end portion 822 may
be subjected to mirror polishing and subsequently thermal etching, and the resulting
surface may be observed with a scanning transmission electron microscope (STEM) to
check whether a precipitate exists. The kind of the additional elements that exist
may be identified in a manner in which the concentration of the additional elements
is measured near the crystal grain boundary in an image obtained by the STEM with
an energy dispersive X-ray spectrometer (EDS). A magnification during the observation
with the STEM may be 5000 times or more.
[0031] The content of the additional elements of the heating coil 820 that the glow plug
10 includes can be measured in the following manner. That is, after the heating coil
820 is detached from the sheath heater 800 and the insulator 870 is mechanically removed,
the content may be measured by ICP atomic emission spectroscopy (high frequency inductively
coupled plasma atomic emission spectroscopy). In the case where the content of the
additional elements in the coil front-end portion 822 located in the melt portion
816 is measured, a component of the sheath tube 810 may be removed from the surface
of the wire by using a mechanical method or an acid before the measurement.
[0032] The additional elements that exist at the crystal grain boundary in the surface layer
825 of the heating coil 820 may exist in a state of a reduced metal or a state of
an oxide. The majority of the additional elements typically exist in a state of an
oxide because the additional elements are exposed to a high temperature during manufacturing
processes of the glow plug 10. In the case where the additional elements exist in
a state of an oxide at the grain boundary, the additional elements, which exist as
an oxide, are more stable than in the case where the additional elements exist as
a metal, and the stability of the effect of inhibiting metal diffusion from the melt
portion into the heating coil can be improved. That is, in the case where the additional
elements exist in a state of a reduced metal, the grain of a metallic precipitate
grows when the metallic precipitate is exposed to a high temperature during the use
of the glow plug 10. This causes the additional elements dispersed at the crystal
grain boundary to aggregate, the locations at which metal diffusion is prevented by
the additional elements at the crystal grain boundary decrease, and the effect of
inhibiting metal diffusion gradually decreases. In the case where at least some of
the additional elements exist as an oxide, which is more stable (more unlikely to
aggregate) than a metal, the effect of inhibiting metal diffusion can be stable for
a longer period of time.
[0033] Whether the additional elements exist as an oxide can be checked by measurement with
the EDS, that is, by measurement of the concentration of the additional elements and
oxygen atoms near the crystal grain boundary.
(A-4) Method of Manufacturing Glow Plug
[0034] Fig. 4 is a flow chart illustrating a method of manufacturing the glow plug 10. The
manufacture of the glow plug 10 begins with welding of the heating coil 820, the control
coil 830, and the center rod 200 (step T100). Specifically, the heating coil 820 and
the control coil 830 are welded to each other, and the control coil rear-end portion
839 and the center rod front-end portion 210 are welded to each other. Subsequently,
the coil front-end portion 822 and the front-end portion of the sheath tube 810 are
welded to each other (step T110). In the step T110, a process of welding the coil
front-end portion 822 and the front-end portion of the sheath tube 810 is also referred
to as a "welding process".
[0035] Figs. 5A and 5B illustrate the welding process in the step T110. In Figs. 5A and
5B, the front-end portions of the sheath tube 810 and the heating coil 820 are illustrated,
and the sheath tube 810 is illustrated by its section. In the welding process, an
extension 810p that is a tubular member extending in the axial direction OD is first
prepared as a member for forming the sheath tube 810. The extension 810p includes
a front-end portion 813p having an opening 815 and is formed such that the diameter
gradually decreases toward the opening 815. The coil front-end portion 822 is inserted
into the front-end portion 813p (opening 815) of the prepared extension 810p and located
there (Fig. 5A). Subsequently, the front-end portion 813p is melted by, for example,
arc welding from the outside of the front-end portion 813p and solidified to close
the opening 815, and the coil front-end portion 822 and the sheath tube front-end
portion 813 are welded to each other (Fig. 5B). In this way, the coil front-end portion
822 is surrounded by and embedded in the melt portion 816. At this time, in the case
where welding is performed under conditions in which the heating coil 820 does not
melt, the melt portion 816, which does not substantially contain the component of
the heating coil 820, is formed.
[0036] After the welding process in the step T110 is finished, the insulator 870 is filled
in the sheath tube 810 (step T120). The insulator 870 covers the heating coil 820,
the control coil 830, and the center rod 200 and is filled in the gap formed in the
sheath tube 810. The assemble of the sheath heater 800 is finished.
[0037] After the sheath heater 800 is assembled, the sheath heater 800 is subjected to a
swaging process (step T130). The swaging process is a process of applying a striking
force to the sheath heater 800 to decrease the diameter of the sheath heater 800 and
densifying the insulator 870 filled in the sheath tube 810. When a striking force
is applied to the sheath heater 800 by swaging, the striking force is transmitted
to the inside of the sheath heater 800, and the insulator 870 is densified.
[0038] After the sheath heater 800 is subjected to the swaging process, the sheath heater
800 and the metal shell 500 are assembled together, and the glow plug 10 is assembled
(step T140) to complete the glow plug 10. Specifically, the sheath heater 800 integrated
with the center rod 200 is press-fitted into the axial hole 510 of the metal shell
500 and secured thereto, the O-ring 460 and the insulating member 410 are engaged
with the center rod 200 at the rear-end portion of the metal shell 500, and the engagement
member 100 is tightened with the external thread portion 290 of the center rod 200
formed at the rear end of the metal shell 500. In the step T140, the glow plug 10
is subjected to an aging process. Specifically, transmission of electricity to the
assembled glow plug 10 causes the sheath heater 800 to generate heat, and an oxide
film is formed on the outer surface of the sheath heater 800.
[0039] In the glow plug 10 with the above structure according to the first embodiment, the
additional elements exist at the crystal grain boundary of the main component of which
the heating coil 820 is composed at least in the surface layer 825 of the coil front-end
portion 822 of the heating coil 820 containing at least one selected from tungsten
(W) and molybdenum (Mo) as the main component. Accordingly, during heating by the
sheath heater 800, at least one metal selected from nickel (Ni) and iron (Fe) and
contained in the melt portion 816 can be inhibited from diffusing from the melt portion
816 into the heating coil 820 along the crystal grain boundary of the main component
of which the heating coil 820 is composed. Consequently, the melting point of the
heating coil 820 can be inhibited from decreasing due to diffusion of the metal of
which the sheath tube 810 is composed into the heating coil 820. Accordingly, the
heating coil 820 is inhibited from melting and becoming disconnected when the glow
plug 10 is used, and the durability of the glow plug 10 can be improved. In addition,
in the case where the additional elements exist at the crystal grain boundary of the
main component in the surface layer 825, the grain boundary embrittlement in the heating
coil 820 is inhibited from progressing, and the durability of the sheath heater 800
and the glow plug 10 can be inhibited from decreasing.
[0040] In particular, the temperature of the front-end portion (for example, a portion about
2 mm from the front-end portion of the sheath heater 800 toward the rear-end side
in the axial direction OD) of the heating coil 820 becomes high during heating by
the sheath heater 800. According to the first embodiment, Ni or Fe of which the sheath
tube 810 is composed can be greatly inhibited from diffusing at such a high-temperature
portion, and accordingly, the heating coil 820 can be greatly inhibited from becoming
disconnected.
B. Second Embodiment
[0041] Fig. 6 is an enlarged schematic sectional view of the structure of the front-end
portion of a sheath heater 800a according to a second embodiment as in Fig. 3. The
sheath heater 800a according to the second embodiment is used with the sheath heater
800a installed in the glow plug 10 instead of the sheath heater 800 according to the
first embodiment. In the second embodiment, components shared with the first embodiment
are designated by like reference numbers, and a detailed description thereof is omitted.
[0042] According to the second embodiment, a coil front-end portion 822a, which is the front-end
portion of a heating coil 820a, is joined to the sheath tube 810 with the coil front-end
portion 822a embedded in the melt portion 816, as in the first embodiment. According
to the second embodiment, however, the coil front-end portion 822a is not formed so
as to extend linearly in the axial line O, but the entire heating coil 820a is spirally
wound as in the case of the spiral portion 823 according to the first embodiment.
In the case where the sheath heater 800a is manufactured, when the extension 810p
and the heating coil 820a are welded to each other, as illustrated in Fig. 5A and
Fig. 5B, the spiral coil front-end portion 822a may be inserted into the opening 815
of the front end of the extension 810p. The front-end portion 813p may be melted by,
for example, arc welding from the outside of the front-end portion 813p and solidified
to close the opening 815, and the coil front-end portion 822a and the sheath tube
front-end portion 813 may be welded to each other.
[0043] With this structure, the additional elements exist at the crystal grain boundary
of the main component of the heating coil 820a at least in the surface layer 825 of
the coil front-end portion 822a embedded in the melt portion 816, and accordingly,
the same effects as in the first embodiment can be achieved.
C. Third Embodiment
[0044] Fig. 7 is an enlarged explanatory view of the structure of the front-end portion
of a sheath heater 800b according to a third embodiment. The sheath heater 800b according
to the third embodiment is used with the sheath heater 800b installed in the glow
plug 10 instead of the sheath heater 800 according to the first embodiment. In the
third embodiment, components shared with the first embodiment are designated by like
reference numbers, and a detailed description thereof is omitted. In Fig. 7, a sheath
tube 810b and the insulator 870 are illustrated by their section.
[0045] The sheath tube 810b forming the sheath heater 800b includes an extension 811 and
a lid portion 812b. The extension 811 is a cylindrical member that extends in the
axial direction OD and that forms the entire side surface of the sheath tube 810b.
The lid portion 812b is located at the front end of the extension 811 such that an
outer surface thereof is exposed to the outside of the sheath tube 810b and closes
the front-end portion of the sheath tube 810b. The coil front-end portion 822 is joined
to the lid portion 812b by welding. Specifically, the lid portion 812b and the coil
front-end portion 822 are connected to each other with the melt portion 816 interposed
therebetween. According to the third embodiment, the extension 811 and the lid portion
812b are joined to each other by welding, and a joint 817 is formed between the extension
811 and the lid portion 812b. According to the third embodiment, a discoid member
having a constant thickness is used as the lid portion 812b, and the joint 817 is
formed in an annular shape extending through the sheath tube 810b in the thickness
direction.
[0046] The melt portion 816 is a joint at which the lid portion 812b has melted. The joint
817 is a joint at which at least one of the lid portion 812b and the extension 811
has melted. The extension 811 can be formed of the same material as the sheath tube
810 according to the first embodiment. The compositions of the extension 811 and the
lid portion 812b may be the same or different. The lid portion 812b, however, contains
at least one metal selected from nickel (Ni) and iron (Fe). Accordingly, the melt
portion 816 also includes at least one metal selected from nickel (Ni) and iron (Fe).
[0047] When the sheath heater 800b is manufactured, the coil front-end portion 822 and the
lid portion 812b are first welded to each other to form the melt portion 816 in the
step T110 in Fig. 4. At this time, the lid portion 812b may have at the central portion
a through-hole or a recessed portion for inserting and welding the coil front-end
portion 822. In the welding process, the coil front-end portion 822 does not substantially
melt, and the lid portion 812b melts, so that the melt portion 816 is formed. The
heating coil 820 the front end of which is welded to the lid portion 812b may be inserted
into the extension 811, and the lid portion 812b may be welded to the front end of
the extension 811 to form the joint 817.
[0048] With this structure, the additional elements exist at the crystal grain boundary
of the main component of the heating coil 820 at least in the surface layer 825 of
the coil front-end portion 822 embedded in the melt portion 816, and accordingly,
the same effects as in the first embodiment can be achieved.
[0049] The lid portion 812b can be formed in various shapes other than a discoid shape.
The joint 817 that joints the lid portion 812b and the extension 811 to each other
may be formed in a shape other than an annular shape extending through the sheath
tube 810b in the thickness direction. For example, the melt portion 816 and the joint
817 may at least partially overlap.
D. Fourth Embodiment
[0050] Fig. 8 is an enlarged explanatory view of the structure of the front-end portion
of a sheath heater 800c according to a fourth embodiment. The sheath heater 800c according
to the fourth embodiment is used with the sheath heater 800c installed in the glow
plug 10 instead of the sheath heater 800 according to the first embodiment. In the
fourth embodiment, components shared with the first to third embodiments are designated
by like reference numbers, and a detailed description thereof is omitted. In Fig.
8, components other than the heating coil 820a are illustrated by their section.
[0051] A sheath tube 810c forming the sheath heater 800c includes the extension 811 and
a lid portion 812c. The lid portion 812c is formed in a cylindrical shape with a step
including a thinner closing portion 840 and a thicker protrusion 842, that is, in
a rivet shape. The closing portion 840 closes the front-end portion of the sheath
tube 810c while the front-end surface thereof is exposed to the outside. The protrusion
842 is formed so as to protrude from the closing portion 840 to the inside of the
sheath tube 810c and is joined to the coil front-end portion 822a of the heating coil
820a by welding. Specifically, the protrusion 842 and the coil front-end portion 822a
are connected to each other with the melt portion 816 interposed therebetween. According
to the fourth embodiment, the extension 811 and the closing portion 840 are also joined
to each other by welding, and the joint 817 is formed between the extension 811 and
the closing portion 840. The joint 817 is formed in an annular shape extending through
the sheath tube 810c in the thickness direction.
[0052] The melt portion 816 is a joint at which the lid portion 812c (protrusion 842) has
melted. The joint 817 is a joint at which at least one of the lid portion 812c (closing
portion 840) and the extension 811 has melted. The extension 811 can be formed of
the same material as the sheath tube 810 according to the first embodiment. The compositions
of the extension 811 and the lid portion 812c may be the same or different. The lid
portion 812c, however, contains at least one metal selected from nickel (Ni) and iron
(Fe). Accordingly, the melt portion 816 also includes at least one metal selected
from nickel (Ni) and iron (Fe).
[0053] According to the fourth embodiment, the coil front-end portion 822a is not embedded
in the melt portion 816 formed in the sheath tube 810c but is wound around the outer
circumference of the protrusion 842. The melt portion 816 is formed in a region including
the outer surface of the protrusion 842 in contact with the coil front-end portion
822a of the heating coil 820a. The additional elements exist at the crystal grain
boundary of the main component of the heating coil 820a at least in the surface layer
825 of the coil front-end portion 822a in contact with the melt portion 816 at the
protrusion 842, as in the first embodiment.
[0054] When the sheath heater 800c is manufactured, the coil front-end portion 822a is first
wound around and welded to the protrusion 842 of the lid portion 812c to form the
melt portion 816 in the step T110 in Fig. 4. In the welding process, the coil front-end
portion 822a does not substantially melt, and the protrusion 842 melts, so that the
melt portion 816 is formed. The heating coil 820a the front end of which is welded
to the lid portion 812c may be inserted into the extension 811, and the closing portion
840 of the lid portion 812c may be welded to the front end of the extension 811 to
form the joint 817.
[0055] With this structure, the additional elements exist at the crystal grain boundary
of the main component of the heating coil 820a at least in the surface layer 825 of
the coil front-end portion 822a in contact with the melt portion 816 formed at the
protrusion 842, and accordingly, the same effects as in the first embodiment can be
achieved.
[0056] The joint 817 that joints the lid portion 812c and the extension 811 to each other
may be formed in a shape other than an annular shape extending through the sheath
tube 810c in the thickness direction. For example, the joint 817 may be formed of
the whole of a portion of the closing portion 840 that is exposed to the outside of
the sheath tube 810c. Alternatively, the joint 817 may be formed so as to extend to
at least a part of the protrusion 842.
E. Modification
First Modification
[0057] According to the above embodiments, the melt portion 816 is formed as a result of
the sheath tube 810, 810b, or 810c only being melted and does not substantially contain
the material of which each heating coil is composed. However, a different structure
may be used. For example, a mixed layer containing the material of which each heating
coil is composed may be formed in a region (region including the boundary with the
coil front-end portion) of the melt portion 816 near the surface of the heating coil.
That is, the melt portion 816 may contain the material of which each heating coil
is composed, provided that the melt portion 816 contains the same material as a portion
of the sheath tube other than the melt portion 816. Also, in this case, it is only
necessary for the additional elements to exist at the crystal grain boundary of the
main component of the heating coil at least within the range in which the distance
from the above boundary in the cross section of the coil front-end portion is equal
to a length of a quarter of the diameter of the wire forming the coil front-end portion.
Second Modification
[0058] According to the above embodiments, the sheath heaters 800 and 800a to 800c have
the heating coils 820 and 820a and the control coil 830. However, a different structure
may be used. For example, a single coil in which the rear-end portion of the heating
coil is connected to the center rod front-end portion 210 may be provided. Alternatively,
three or more coils connected to each other in series may be provided. Also in this
case, it is only necessary for the additional elements to exist at the crystal grain
boundary at least in the surface layer 825 of the coil front-end portion of the heating
coil that is located at the front-end portion and that is welded to the sheath tube.
Third Modification
[0059] According to the third and fourth embodiments, the extension 811 and the lid portions
812b and 812c are joined to each other by welding with the joint 817 interposed therebetween.
However, a different structure may be used. For example, the extension 811 and the
lid portions 812b and 812c may be joined by, for example, a crimping method.
EXAMPLE
[0060] Various glow plugs were manufactured as samples having different kinds of additional
elements added to the heating coil 820 and different contents of the additional elements
of the heating coil 820. The presence or absence of a precipitate at the crystal grain
boundary and the durability of the glow plugs were evaluated. The results will be
described below.
[0061] Fig. 9 and Fig. 10 illustrate the summary of the kind of the additional elements,
the content of the additional elements, and the evaluation results of the samples.
When the samples were manufactured, the heating coils 820 formed of different tungsten
(W) wires having a diameter of 0.2 mm and containing different contents of various
kinds of additional elements other than tungsten were prepared, and the sheath heaters
800 were manufactured, and the glow plugs 10 were assembled. At this time, regarding
the samples in which the compositions of the heating coils 820 are different from
each other, the heating coils 820 were manufactured under the same conditions, and
the glow plugs 10 were assembled. Regarding some of the heating coils 820 of the samples,
which were manufactured under the same conditions, after the glow plugs 10 were assembled,
the content of the additional elements contained in each heating coil 820 was investigated.
Regarding other heating coils 820 of the samples, which were manufactured under the
same conditions, after the glow plugs 10 were assembled, whether the additional elements
existed at the crystal grain boundary at least in the surface layer of the coil front-end
portion of each heating coil was investigated. Regarding the samples, after the glow
plugs 10 were assembled, the other heating coils 820, which were manufactured under
the same conditions, were used for operational durability tests of the glow plugs
10.
[0062] Among samples 1 to 29 illustrated in Fig. 9 and Fig. 10, the samples 1 to 23 illustrated
in Fig. 9 contain only one kind of additional elements. In contrast, the samples 24
to 29 illustrated in Fig. 10 contain several kinds of additional elements selected
from potassium (K), aluminum (Al), silicon (Si), lanthanum (La), thorium (Th), and
cerium (Ce). Specifically, the heating coils 820 of the samples 24 to 29 were manufactured
in a manner in which two kinds of additional elements were added in the same amount.
[0063] The sheath heaters and the glow plugs were manufactured in accordance with the first
embodiment (for example, Fig. 2). The front-end portion of each heating coil 820 was
welded directly to the sheath tube. The kind and content of the additional elements
of the heating coil 820 of each sample are illustrated in Fig. 9 and Fig. 10. The
other conditions (shape of the components and the material of each component other
than the heating coil) are the same in all of the samples.
Measurement of Content of Additional Elements
[0064] Each sample glow plug 10 was disassembled, and each heating coil 820 was detached
from the sheath heater. After the insulator 870 was mechanically removed, the content
of the additional elements of the heating coil 820 was measured by ICP atomic emission
spectroscopy (high frequency inductively coupled plasma atomic emission spectroscopy).
The content of the additional elements thus measured was substantially equal to the
amount of the additional elements added to a raw material (tungsten) when the heating
coil 820 was manufactured.
Check of Additional Elements at Crystal Grain Boundary
[0065] It was determined whether the additional elements existed at the crystal grain boundary
of the main component (tungsten) of which the heating coil 820 was composed in the
surface layer 825 of the heating coil 820 of each sample. For this purpose, the cross
section of the coil front-end portion 822 was subjected to mirror polishing and subsequently
thermal etching, and the resulting surface was observed with a scanning transmission
electron microscope (STEM) to check whether a precipitate existed at the crystal grain
boundary. The concentration of the additional elements at the crystal grain boundary
in an image obtained by the STEM was measured with an energy dispersive X-ray spectrometer
(EDS), and it was thereby confirmed that the additional elements caused the observed
precipitate to be produced. The magnification during the observation by the STEM was
5000 times. In Fig. 9, the column of "PRECIPITATE" includes the term "PRESENCE" in
the case where the presence of the additional elements at the crystal grain boundary
of the main component was confirmed. The column of "PRECIPITATE" includes the term
"ABSENCE" in the case where the presence of the additional elements at the crystal
grain boundary of the main component was not confirmed. Regarding the samples in which
the presence of the additional elements at the crystal grain boundary of the main
component was confirmed, it was confirmed from the result of the EDS that at least
some of the additional elements existed as an oxide at the crystal grain boundary.
Condition of Operational Durability Test
[0066] An operational test was conducted by using each sample glow plug 10 to evaluate the
durability thereof. Specifically, a process having a cycle of the following procedures
1 to 3 was repeatedly performed on each sample, and the number of the cycles (number
of disconnection cycles) the heating coil 820 of each sample became disconnected was
measured. (Procedure 1) Electricity was transmitted to each sample glow plug such
that the temperature of the sheath heater at a location 2 mm from the front-end portion
of the outer surface of the sheath heater in the axial direction OD became 1200°C.
(Procedure 2) After the temperature of the sheath heater at the above location became
1200°C, the transmission of electricity to the glow plug 10 was continued for 10 minutes
while a state where the temperature of the sheath heater at the above location was
1200°C was maintained. (Procedure 3) The transmission of electricity to the glow plug
was stopped after the state where the temperature of the sheath heater at the above
location was 1200°C was maintained for 10 minutes, and the sheath heater was cooled
for 2 minutes in a manner in which air was sent thereto (air at a wind speed of 10
mm/s).
Determination of Location of Disconnection
[0067] During the operational durability test of each sample glow plug, after the heating
coil 820 became disconnected, the location of the disconnection was checked. The location
of the disconnection was checked with an X-ray CT apparatus. Specifically, the location
of the disconnection of the heating coil 820 was identified in an X-ray CT image enlarged
1000 times. The location of the disconnection was measured by using as a criterion
the location of the rear end of a region of the heating coil 820 in which the component
of the sheath tube 810 existed on the surface. The location (also referred to below
as the "tube component rear-end location") of the rear end of the region of the heating
coil 820 in which the component of the sheath tube 810 existed on the surface refers
to the location of a region of the surface of the heating coil 820 in contact with
the melt portion 816 on the rear-end side in the axial direction OD.
[0068] In Fig. 9, the column of "FRONT END OF DISCONNECTED PORTION" includes the symbol
"x" in the case where the location of the disconnection was a location within 10 mm
from the tube component rear-end location on the rear-end side in the axial direction
OD. The column of "FRONT END OF DISCONNECTED PORTION" includes the symbol "O" in the
case where the location of the disconnection was further away than the location 10
mm from the tube component rear-end location on the rear-end side in the axial direction
OD. In the case where the location of the disconnection is the location within 10
mm from the tube component rear-end location on the rear-end side in the axial direction
OD (in the case where the evaluation of "FRONT END OF DISCONNECTED PORTION" is "x"),
it is thought that the cause of the disconnection of the heating coil 820 is that
the metal of which the sheath tube 810 is composed diffuses into the heating coil
820 and that the melting point of the heating coil 820 locally decreases. In the case
where the location of the disconnection is further away than the location 10 mm from
the tube component rear-end location on the rear-end side in the axial direction OD
(in the case where the evaluation of "FRONT END OF DISCONNECTED PORTION" is "O"),
it is thought that the cause of the disconnection of the heating coil 820 is not that
the metal of which the sheath tube 810 is composed diffuses into the heating coil
820 and that the melting point of the heating coil 820 locally decreases.
Presence or Absence of Sheath Tube Penetration
[0069] When each sample was observed with the X-ray CT apparatus, whether a through-hole
was formed in the side surface portion 814 of the sheath tube 810 was also checked.
In Fig. 9, the column of "TUBE PENETRATION" includes the symbol "+" in the case where
a through-hole was formed in the side surface portion 814 of the sheath tube 810,
and the column of "TUBE PENETRATION" includes the symbol "-" in the case where no
through-hole was formed.
[0070] As the transmission of electricity to each glow plug 10 was repeated, oxidation in
the sheath tube 810 gradually progresses, and there is a possibility that a through-hole
is finally formed. In the case where the through-hole is formed in the sheath tube
810, oxygen enters the sheath heater via the through-hole. When oxygen enters the
sheath heater, tungsten (W) of which the heating coil 820 is composed is oxidized,
and the melting point of the heating coil 820 locally decreases. Accordingly, it is
thought that, in the case where the through-hole is formed in the sheath tube 810,
the cause of the disconnection of the heating coil 820 is the oxidation of tungsten
due to oxygen that enters via the through-hole.
[0071] As illustrated in Fig. 9, in the samples 1 and 2 in which the content of the additional
elements was less than 5 ppm, specifically, 2 ppm and 4 ppm, the presence of the additional
elements at the crystal grain boundary of tungsten in the surface layer 825 of the
heating coil 820 was not confirmed. In the samples 1 and 2, the location of the disconnection
of the heating coil 820 was the location within 10 mm from the tube component rear-end
location on the rear-end side in the axial direction OD. Accordingly, it is thought
that, in the samples 1 and 2, the metal of which the sheath tube 810 was composed
was not inhibited from diffusing into the heating coil 820, and the heating coil 820
became disconnected near the tube component rear-end location, because the presence
of the additional elements at the crystal grain boundary of tungsten in the surface
layer 825 of the heating coil 820 was not confirmed. The disconnection cycle of the
samples 1 and 2 was less than ten thousand cycles. From the above result, in Fig.
9, the column of "DECISION" for the samples 1 and 2 includes the symbol "x".
[0072] As illustrated in Fig. 9, in the samples 3 to 20 in which the content of the additional
elements was no less than 5 ppm and no more than 200 ppm, the presence of the additional
elements at the crystal grain boundary of tungsten in the surface layer 825 of the
heating coil 820 was confirmed. In the samples 3 to 20, the location of the disconnection
of the heating coil 820 was further away than the location 10 mm from the tube component
rear-end location on the rear-end side in the axial direction OD. The presence of
the through-hole in the sheath tube 810 of the samples 3 to 20 was confirmed. Accordingly,
it is thought that the cause of the disconnection of the heating coil 820 of the samples
3 to 20 was not diffusion of the metal of which the sheath tube 810 was composed into
the heating coil 820 but was the oxidation of the heating coil 820 (tungsten) due
to oxygen that entered via the through-hole. The disconnection cycle of the samples
3 to 20 was more than ten thousand cycles. From the above result, in Fig. 9, the column
of "DECISION" for the samples 3 to 20 includes the symbol "⊙".
[0073] As illustrated in Fig. 9, in the samples 21 to 23 in which the content of the additional
elements was more than 200 ppm, the presence of the additional elements at the crystal
grain boundary of tungsten in the surface layer 825 of the heating coil 820 was confirmed.
In the samples 21 to 23, the location of the disconnection of the heating coil 820
was further away than the location 10 mm from the tube component rear-end location
on the rear-end side in the axial direction OD. The presence of a through-hole in
the sheath tube 810 of the samples 21 to 23 was not confirmed.
[0074] The location of the disconnection was further away than the location 10 mm from the
tube component rear-end location on the rear-end side in the axial direction OD, as
described above. For this reason, it is thought that the cause of the disconnection
of the heating coil 820 of the samples 21 to 23 was not diffusion of the metal of
which the sheath tube 810 was composed into the heating coil 820. Since the presence
of a through-hole in the sheath tube 810 was not confirmed, it is thought that the
cause of the disconnection of the heating coil 820 of the samples 21 to 23 was not
oxidation of the heating coil 820 due to oxygen that entered via the through-hole.
It is however thought that, in the samples 21 to 23, the content of the additional
elements of the heating coil 820 was large, the additional elements and the insulator
870 (MgO) reacted with each other and excessively adhered to each other, and the heating
coil 820 became disconnected due to a stress caused by a difference in the thermal
expansion coefficient between the heating coil 820 and the insulator 870.
[0075] With the samples 21 to 23, an effect of the present invention, that is, inhibiting
disconnection due to diffusion of the metal of which the sheath tube 810 was composed
was achieved. However, there was a tendency that the additional metal reacted with
MgO selected as the material of which the insulator 870 was composed, and the disconnection
cycle was thereby less than in the case where the content of the additional elements
was 200 ppm or less (specifically, the disconnection cycle was less than ten thousand
cycles). From the above result, in Fig. 9, the column of "DECISION" for the samples
21 to 23 includes the symbol "O".
[0076] As illustrated in Fig. 10, in the samples 24 to 28 among samples containing two kinds
of additional elements in which the content of the additional elements was no less
than 5 ppm and no more than 200 ppm, the presence of the additional elements at the
crystal grain boundary of tungsten in the surface layer 825 of the heating coil 820
was confirmed. The location of the disconnection of the heating coil 820 was further
away than the location 10 mm from the tube component rear-end location on the rear-end
side in the axial direction OD. The presence of the through-hole in the sheath tube
810 was confirmed. Accordingly, it is thought that the cause of the disconnection
of the heating coil 820 of the samples 24 to 28 was not diffusion of the metal of
which the sheath tube 810 was composed into the heating coil 820 but was the oxidation
of the heating coil 820 (tungsten) due to oxygen that entered via the through-hole,
as in the case of the samples 3 to 20. The disconnection cycle of the samples 24 to
28 was more than ten thousand cycles. From the above result, in Fig. 10, the column
of "DECISION" for the samples 24 to 28 includes the symbol "⊙".
[0077] As illustrated in Fig. 10, in the sample 29 among the samples containing two kinds
of additional elements in which the content of the additional elements was more than
200 ppm, the presence of the additional elements at the crystal grain boundary of
tungsten in the surface layer 825 of the heating coil 820 was confirmed. The location
of the disconnection of the heating coil 820 was further away than the location 10
mm from the tube component rear-end location on the rear-end side in the axial direction
OD. The presence of a through-hole in the sheath tube 810 was not confirmed. Accordingly,
it is thought that the cause of the disconnection of the heating coil 820 of the sample
29 was that the additional elements and the insulator 870 (MgO) reacted with each
other and excessively adhered to each other, as in the samples 21 to 23. With the
sample 29, an effect of the present invention, that is, inhibiting disconnection due
to diffusion of the metal of which the sheath tube 810 was composed was achieved.
However, the additional elements and the insulator 870 (MgO) reacted with each other,
and the disconnection cycle was thereby less than ten thousand cycles. Accordingly,
the column of "DECISION" includes the symbol "○".
[0078] The present invention is limited neither to the above embodiments, the example, nor
the modifications and can be achieved with various structures without departing from
the concept of the present invention. For example, the technical features in the embodiments,
the example, and the modifications corresponding to the technical features in the
aspects described in the summary of the invention can be appropriately replaced or
combined in order to solve part or all of the above problems or in order to achieve
part or all of the above effects. Technical features described as unessential features
can be appropriately removed.