JP2007212195A - Temperature sensor and method for manufacturing same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a temperature sensor capable of preventing any open circuit occurring in an electrode line, and to provide a method for manufacturing the temperature sensor. <P>SOLUTION: The temperature sensor 1 comprises: a thermistor element 2 having a pair of electrode lines 21; a sheath pin 3 containing a pair of signal lines 31 which are connected with the pair of electrode lines 21 respectively, so as to expose the signal lines 31 on the head edge side; a cover 4 being disposed at the head section so as to cover the thermistor element 2; a cement 5 being disposed so as to connect and fix the pair of electrode lines 21; and an insulating/holding member for fixing the cement 5 so as to hold the cement 5 around the electrode lines 21. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a temperature sensor using a thermistor element and a method for manufacturing the same.

As a temperature sensor that measures the temperature of an automobile exhaust gas or the like, there is a temperature sensor that uses a thermistor element whose resistance value changes depending on the temperature (see Patent Document 1).
As shown in FIG. 18, the temperature sensor 9 includes a thermistor element 92 provided with a pair of electrode wires 921, a sheath pin 93 containing a pair of signal wires 931 connected to the pair of electrode wires 921, respectively, and the thermistor. And a cover 94 disposed at the tip so as to cover the element 92. A cement 95 having excellent thermal conductivity is filled between the thermistor element 92 and the cover 94.

  However, in the conventional gas sensor 9, when the cover 95 is filled with the cement 95, the air is not sufficiently removed, and the gap between the electrode wires 921 is not filled with the cement 95 as shown in FIG. There is a possibility that the portion 99 is easily formed. Therefore, when the vibration of the internal combustion engine is transmitted from the exhaust pipe or the like to the temperature sensor 9 via the housing (not shown), the vibration is also transmitted to the thermistor element 92 disposed in the interior 940, and stress is applied to the electrode wire 921. There is a possibility that the electrode wire 921 may be disconnected due to concentration.

  Further, a temperature sensor has been proposed in which an insulator member 96 having a substantially E-shaped cross section in a direction orthogonal to the axial direction is provided between a thermistor element and a sheath pin (see Patent Document 2). . A groove portion 962 is formed in the lever member 96, and an electrode wire is disposed in the groove portion 962.

However, in the above configuration, since the groove portion 962 and the electrode wire are not in close contact with each other, a gap is generated, and the electrode wire in the groove portion 962 may be insufficiently fixed. For this reason, it is difficult to sufficiently suppress the vibration of the thermistor element, and there is a possibility that stress concentrates on the electrode wire and the electrode wire is disconnected.
In order to prevent this, the groove 962 and the electrode wire are brought into close contact with each other, so that it is necessary to improve the processing accuracy of the insulator member 96, and the production efficiency of the temperature sensor is lowered and the production cost is increased. Arise.

JP 2004-317499 A JP 2002-267547 A

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a temperature sensor that can prevent disconnection of an electrode wire and a method for manufacturing the same.

The first invention comprises a thermistor element provided with a pair of electrode wires;
A sheath pin containing a pair of signal wires connected to the pair of electrode wires in a state of being exposed on the tip side,
A cover disposed at the tip so as to cover the thermistor element;
Cement arranged to connect and fix the pair of electrode wires;
A temperature sensor comprising: an insulating holding member to which the cement is fixed so as to hold the cement around the electrode wire.

Next, the effects of the present invention will be described.
The temperature sensor of the present invention includes the cement arranged to connect and fix the pair of electrode wires, and an insulating holding member to which the cement is fixed. Therefore, the cement can be easily and sufficiently filled between the insulating holding member and the electrode wire while being in contact with the insulating holding member and the electrode wire. That is, if there is no insulating holding member, it is difficult to place cement so as to connect a pair of electrode wires. Therefore, the cement can be easily arranged between the pair of electrode wires by arranging the insulating holding member around the electrode wires and arranging the insulation holding members to hold the cement.

  Thereby, between the pair of electrode wires, it is possible to prevent formation of a void portion in which air is not completely removed and is not filled with cement. Therefore, the electrode wire can be sufficiently fixed, and even if the vibration of the internal combustion engine or the like is transmitted through an exhaust pipe or the like and the temperature sensor vibrates, the thermistor element is prevented from vibrating. Can do. As a result, it is possible to prevent stress from concentrating on the electrode wire and disconnecting the electrode wire.

  As described above, according to the present invention, it is possible to provide a temperature sensor that can prevent disconnection of an electrode wire.

The second invention covers a thermistor element provided with a pair of electrode wires, a sheath pin containing a pair of signal lines respectively connected to the pair of electrode wires in a state of being exposed at the tip side, and the thermistor element Temperature sensor having a cover disposed at the tip end portion, a cement disposed so as to connect the pair of electrode wires, and an insulating retaining member for retaining the cement around the electrode wires In manufacturing
Placing the insulation holding member around the electrode wire, and placing the cement in contact with the insulation holding member and the electrode wire, a cement placement step,
A cement drying process for drying and solidifying the cement;
Thereafter, there is an element insertion step of inserting the integrated thermistor element, the electrode wire, the cement, and the insulating holding member into the cover, and the temperature sensor manufacturing method ( Claim 10).

  The manufacturing method of the temperature sensor of this invention has the cement arrangement | positioning process which arrange | positions the said insulation holding member around the said electrode wire, and arrange | positions the said cement in contact with the said insulation holding member and the said electrode wire. Thereby, the cement can be easily and sufficiently filled between the insulating holding member and the electrode wire. That is, if there is no insulating holding member, it is difficult to place cement so as to connect a pair of electrode wires. Therefore, the cement can be easily arranged between the pair of electrode wires by arranging the insulating holding member around the electrode wires and arranging the insulation holding members to hold the cement.

  Thereby, between the pair of electrode wires, it is possible to prevent formation of a void portion in which air is not completely removed and is not filled with cement. Therefore, the electrode wire can be sufficiently fixed, and even if the vibration of the internal combustion engine or the like is transmitted through an exhaust pipe or the like and the temperature sensor vibrates, the thermistor element is prevented from vibrating. Can do. As a result, it is possible to prevent stress from concentrating on the electrode wire and disconnecting the electrode wire.

  Moreover, it has the cement drying process which dries and solidifies the said cement. As a result, not only the outer peripheral portion of the cement but also the inside thereof can be sufficiently dried and solidified, so that the formation of the void portion can be sufficiently suppressed particularly between the electrode wires. . As a result, the electrode wire can be sufficiently prevented from being disconnected.

  As described above, according to the present invention, it is possible to provide a method for manufacturing a temperature sensor that can prevent disconnection of an electrode wire.

  In the present specification, the side to be installed in the exhaust pipe of an automobile internal combustion engine or the like will be described as the front end side, and the opposite side as the base end side.

In the first invention (invention 1), the insulating holding member preferably has a substrate portion disposed between the pair of electrode wires (invention 2).
In this case, it is possible to sufficiently prevent the formation of a void portion that is not sufficiently filled with the cement between the pair of electrode wires.

Moreover, it is preferable that the board | substrate part of the said insulation holding member occupies the area | region 90% or more of the space between said pair of electrode wires.
In this case, it is possible to sufficiently prevent a void portion not filled with cement between the pair of electrode wires.
On the other hand, when the region is less than 90% of the space between the pair of electrode wires, the gap portion is easily formed between the pair of electrode wires, so that the electrode wires are sufficiently prevented from being disconnected. May be difficult.

The space between the pair of electrode lines is preferably a space formed by a portion of the electrode line from a root to the thermistor element to a connection portion with the signal line. 4).
Since the space between the base and the connection portion is particularly easily formed as a void portion not filled with cement, the space between the pair of electrode wires is defined as described above, so that the electrode wires Can be sufficiently prevented.

The substrate portion of the insulating holding member preferably has a thickness of 1.16 to 1.5 times the diameter of the electrode wire.
In this case, cement can be more easily filled between the pair of electrode wires, and disconnection of the electrode wires can be sufficiently prevented.

On the other hand, when the thickness is less than 1.16 times the diameter of the electrode wire, there is a possibility that a void portion not filled with cement is likely to be formed.
Further, when the thickness exceeds 1.5 times the diameter of the electrode wire, it may be difficult to dispose the cement between the pair of electrode wires.

In addition, the insulating holding member may be disposed on the side of the pair of electrode wires so as to face the side surfaces of the pair of electrode wires.
Even in this case, the effects of the present invention can be sufficiently exhibited, and the cement can be easily filled between the pair of electrode wires. That is, even if the insulating holding member is not disposed between the pair of electrode wires, the cement can be sufficiently held between the pair of electrode wires by being disposed on the side of the electrode wire. .

Moreover, it is preferable that the clearance gap formed between the said insulation holding member and the said thermistor element is 0.1 mm or less.
Also in this case, it is possible to sufficiently suppress the concentration of stress at the base of the thermistor element in the electrode wire, and it is possible to sufficiently prevent the electrode wire from being disconnected.

The insulating holding member is preferably made of alumina.
In this case, since the insulation holding member has sufficient electrical insulation, it is possible to sufficiently prevent a short circuit between the pair of electrode wires. Moreover, since the insulation holding member excellent in thermal conductivity can be obtained, a temperature sensor excellent in responsiveness can be obtained.

The cement is preferably disposed so that the thickness from the outer peripheral surface of the electrode wire is 0.15 mm or less.
In this case, the inside of the cement can be sufficiently dried and solidified.
On the other hand, when the thickness exceeds 0.15 mm, the outer peripheral portion of the cement is dried and solidified first, which may make it difficult to sufficiently dry and solidify the inside of the cement. Therefore, it may be difficult to sufficiently fix the pair of electrode wires with cement.

In the second invention (Invention 10), it is preferable that the cement drying step is carried out by holding at 150 ° C. or more for 1 hour or more (Invention 11).
In this case, the cement disposed to integrate the thermistor element, the electrode wire, and the insulating holding member before the element insertion step can be sufficiently dried and solidified.
The above temperature of 150 ° C. or higher is a temperature obtained by measuring the thermistor element.

  On the other hand, when the cement drying step is a drying step of less than 150 ° C. or less than 1 hour, it is difficult to sufficiently dry and solidify the inside of the cement, and the pair of electrode wires can be sufficiently fixed. May be difficult. Therefore, there is a possibility that stress concentrates on the electrode wire and the electrode wire is disconnected.

Example 1
A temperature sensor and a manufacturing method thereof according to an embodiment of the present invention will be described with reference to FIGS.
1, 2, 6, and 7, the temperature sensor 1 of this example includes a thermistor element 2 provided with a pair of electrode wires 21 and a pair of signal wires connected to the pair of electrode wires 21, respectively. It has a sheath pin 3 that is incorporated in a state where 31 is exposed to the tip side, and a cover 4 that is disposed at the tip portion so as to cover the thermistor element 2.

  Further, as shown in FIGS. 1, 2, 4, 5, and 7, the temperature sensor 1 includes a primary filling cement 51 arranged to connect and fix a pair of electrode wires 21, and the primary filling cement 51. An insulating holding member 6 to which the primary filling cement 51 is fixed is provided to hold the filling cement 51 around the electrode wire 21.

  In the following, the cement held by the insulating holding member 6 around the pair of electrode wires 21 is the primary filling cement 51, and the cement other than the portion filled with the primary filling cement 51 in the interior 40 of the cover 4 is the secondary filling cement. This will be described as 52. In addition, when only calling it cement 5, it shall refer to these two types of cement.

The temperature sensor 1 of this example will be described in detail below.
The cover 4 is made of stainless steel, and as shown in FIGS. 1, 2, 6, 7 (d) and 7 (e), has a shape in which the tip side is closed in a substantially hemispherical shape. A small-diameter portion 41 disposed around the element 2, a medium-diameter portion 42 disposed around the pair of electrode wires 21, and a large-diameter portion 43 disposed around the sheath pin 3. A first taper portion 44 and a second taper portion 45 are formed between the small diameter portion 41 and the medium diameter portion 42 and between the medium diameter portion 42 and the large diameter portion 43, respectively.

As shown in FIGS. 1, 2, and 6, the cover 4 has a caulking portion 430 for caulking the sheath pin 3 from the outer periphery at the large diameter portion 43, and the caulking portion 430 is welded to the sheath pin 3. Has been.
Further, as shown in FIGS. 1, 2, 6, 7 (d), and 7 (e), the insulating holding member 6, the thermistor element 2, and the cement 5 are accommodated in the interior 40 of the cover 4. ing.

  As shown in FIGS. 1, 2, and 4 to 6, the insulating holding member 6 includes a substrate portion 60 disposed between the pair of electrode wires 21 and a space between the pair of electrode wires 21. 90% or more of the area is occupied. The space between the pair of electrode wires 21 is a space formed by a portion between the root 210 of the electrode wire 21 to the thermistor element 2 and the connection portion 211 with the signal line 31.

Further, the insulating holding member 6 is made of alumina, and as shown in FIGS. 3 to 5, the cross section orthogonal to the axial direction of the temperature sensor 1 has a substantially E shape, and is arranged at the approximate center of the cross section. Two groove portions 62 are provided along the axial direction so as to sandwich the substrate portion 60. A pair of electrode wires 21 is disposed in the two groove portions 62.
Further, the distal end portion of the insulating holding member 6 of this example is in close contact with the proximal end portion of the thermistor element 2.

In the cover 4, as shown in FIGS. 1, 2, and 4 to 7, a pair of electrode wires 21 made of platinum or the like for detecting the thermistor signal is connected to the thermistor element 2. .
Further, as shown in FIGS. 2, 4 to 6, and 7 (a), the electrode wires 21 are spaced apart from each other in parallel, and extend toward the proximal end along the axis of the cover 4. Projecting from the thermistor element 2.

At the base end side of the cover 4, as shown in FIGS. 1, 2, 6, and 7, a sheath pin 3 as an extraction wiring for extracting the thermistor signal from the electrode wire 21 to the outside is an opening 46 of the cover 4. Has been inserted from.
The sheath pin 3 includes a pair of signal wires 31 made of stainless steel, an insulating portion (not shown) made of insulating powder such as magnesia disposed around the signal wire 31, and stainless steel covering the outer periphery of the insulating portion. And an outer tube portion 30. The sheath pin 3 has a cylindrical shape, and the outer tube portion 30 has a cylindrical shape.

  As shown in FIG. 6, the signal line 31 is exposed from the insulating portion and the outer tube portion 30 to the front end side and the rear end side. In addition, as shown in FIGS. 1, 2, 4, 5, and 7, the distal end portion of the signal line 31 and the proximal end portion of the electrode 21 of the thermistor element 2 are welded to form a connection portion 211. Yes. On the other hand, the base end portion of the signal line 31 is connected to an external lead wire (not shown).

  Further, as shown in FIG. 6, the sheath pin 3 is held by a rib 12 made of stainless steel. A protective tube 13 made of stainless steel is attached to the base end side of the rib 12 so as to cover a part of the sheath pin 3 and the external lead wire, and the protective tube 13 is inserted into the housing 14 having the attachment screw 141. It is fixed.

  The temperature sensor 1 is disposed in an exhaust system such as an internal combustion engine (not shown) by screwing a mounting screw 141 into an exhaust pipe. Therefore, the vibration of the internal combustion engine is transmitted from the exhaust pipe to the temperature sensor 1 via the housing 14 and the like, and the vibration is also transmitted to the thermistor element 2 disposed inside the temperature sensor 1.

Next, a manufacturing method of the temperature sensor 1 of this example will be described.
In the manufacturing method of this example, as shown in FIGS. 7A to 7C, the insulating holding member 6 is disposed around the electrode wire 21, and the primary filling cement 51 is replaced with the insulating holding member 6 and the electrode wire 21. A cement disposing step of disposing the first filling cement 51 while drying and solidifying the cement.

In the cement placement step, for example, a primary filling cement 51 in which MgO-based cement is mixed with water to form a mud is prepared. A predetermined amount of the muddy primary filling cement 51 is disposed around the electrode wire 21 on which the insulating holding member 6 is disposed using a dispenser or the like.
In addition, the said primary filling cement 51 is arrange | positioned so that the thickness from the outer peripheral surface of the electrode wire 21 may be 0.15 mm or less as shown in FIG.4, FIG.7 (c).
The cement drying step is performed by holding at 150 ° C. or higher for 1 hour or longer. The temperature of 150 ° C. or higher is a temperature obtained by measuring the thermistor element 2.

Thereafter, as shown in FIG. 7D, there is an element insertion step of inserting the integrated thermistor element 2, electrode wire 21, primary filling cement 51, and insulating holding member 6 into the inside 40 of the cover 4.
In this example, as shown in FIG. 7 (d), the mud-dried secondary filling cement 52 that has been muddy as described above is poured into the inside 40 of the cover 4, and then, as shown in FIG. 7 (e). As shown, the thermistor element 2, the electrode wire 21, and the insulating holding member 6 that are integrated by the primary filling cement 51 through the cement drying step are inserted from the opening 46 of the cover 4 into the interior 40 thereof.
With the above procedure, the cement 5 can be filled over the entire interior 40 of the cover 4 without forming a gap between the pair of electrode wires 21.

Next, the function and effect of this example will be described.
As shown in FIGS. 1 to 5 and FIG. 7, the temperature sensor 1 of the present example fixes a primary filling cement 51 disposed so as to connect and fix a pair of electrode wires 21, and the primary filling cement 51. Insulating holding member 6. Therefore, the primary filling cement 51 can be easily and sufficiently filled between the insulating holding member 6 and the electrode wire 21 while being in contact with the insulating holding member 6 and the electrode wire 21. That is, if the insulation holding member 6 is not provided, it is difficult to arrange the primary filling cement 51 so as to connect the pair of electrode wires 21. Therefore, the insulating holding member 6 is arranged around the electrode wire 21 and is arranged so as to hold the primary filling cement 51 thereon, whereby the primary filling cement 51 can be easily placed between the pair of electrode wires 21. Can be arranged.

  Thereby, between the pair of electrode wires 21, it is possible to prevent the formation of a void portion (see reference numeral 99 in FIG. 18) where air is not completely removed and the primary filling cement 51 is not filled. Therefore, the electrode wire 21 can be sufficiently fixed, and even when the vibration of the internal combustion engine or the like is transmitted through the exhaust pipe or the like and the temperature sensor 1 vibrates, the thermistor element 2 is prevented from vibrating. Can do. As a result, it is possible to prevent the stress from being concentrated on the electrode wire 21 and the electrode wire 21 from being disconnected.

  The manufacturing method of the temperature sensor 1 of this example has a cement drying process which dries and solidifies the primary filling cement 51 as shown in FIG.7 (c). As a result, not only the outer peripheral portion of the primary filling cement 51 but also the inside thereof can be sufficiently dried and solidified, so that the formation of the void portion is sufficiently suppressed particularly between the electrode wires 21. Can do. As a result, the electrode wire 21 can be sufficiently prevented from being disconnected.

Further, as shown in FIGS. 1, 2, and 4 to 6, the insulating holding member 6 includes a substrate portion 60 disposed between the pair of electrode wires 21, so that the above-described between the pair of electrode wires 21 is described above. It is possible to sufficiently prevent the void portion from being formed.
Further, as shown in the figure, since the insulating holding member 6 occupies an area of 90% or more of the space between the pair of electrode wires 21, a gap is formed between the pair of electrode wires 21. This can be prevented sufficiently.

  The space between the pair of electrode wires 21 is from the root 210 of the electrode wire 21 to the thermistor element 2 to the connection portion 211 with the signal wire 31 as shown in FIGS. 1, 2, 4 to 6. It is a space formed by the part between. And the space | gap part which is not filled with the primary filling cement 51 is especially easy to be formed in the said space. Therefore, by defining the space between the pair of electrode wires 21 as described above, disconnection of the electrode wires 21 can be sufficiently prevented.

  The insulating holding member 6 is made of alumina. Therefore, since the insulating holding member 6 has sufficient electrical insulation, a short circuit between the pair of electrode wires 21 can be sufficiently prevented. Moreover, since the insulation holding member 6 excellent in heat conductivity can be obtained, the temperature sensor 1 excellent in responsiveness can be obtained.

Further, as shown in FIG. 4, the primary filling cement 51 has a thickness from the outer peripheral surface of the electrode wire 21 of 0.15 mm or less, so that the inside of the primary filling cement 51 can be sufficiently dried and solidified.
Further, since the cement drying process is performed by holding at 150 ° C. or higher for 1 hour or longer, the thermistor element 2, the electrode wire 21, and the insulating holding member 6 are arranged so as to be integrated before the element insertion process. The filled cement 51 can be sufficiently dried and solidified.

  As described above, according to this example, it is possible to provide a temperature sensor that can prevent disconnection of an electrode wire.

(Example 2)
This example is an example of the temperature sensor 1 in which a gap G of 0.1 mm or less is formed between the insulating holding member 6 and the thermistor element 2 as shown in FIG.
Others are the same as in the first embodiment.
Even if the gap G is formed as in this example, if it is 0.1 mm or less, it is possible to sufficiently suppress the stress from concentrating on the root 210 of the electrode wire 21 to the thermistor element 2. Can be sufficiently prevented.
In addition, the same effects as those of the first embodiment are obtained.

(Example 3)
As shown in FIG. 9, this example is an example of the temperature sensor 1 in which an insulating holding member 6 including a single flat substrate portion 60 is disposed between a pair of electrode wires 21.
The substrate portion 60 of the insulating holding member 6 is disposed so as to be in contact with both the pair of electrode wires 21 and the pair of signal wires 31 and has a diameter of 1.16 of the electrode wire 21 as shown in FIG. It has a thickness t of ~ 1.5 times.
Further, the periphery of the pair of electrode wires 21 is covered with a primary filling cement 51.
Others are the same as in the first embodiment.

Since the substrate portion 60 of the insulating holding member 6 of this example has a thickness t that is 1.16 to 1.5 times the diameter of the electrode wire 21, the primary filling cement 51 can be more easily disposed between the pair of electrode wires 21. The electrode wire 21 can be sufficiently prevented from being disconnected.
In addition, the same effects as those of the first embodiment are obtained.

Example 4
This example is an example of the temperature sensor 1 having an insulating holding member 6 having a substantially H-shaped cross section as shown in FIG.
As shown in the figure, the insulating holding member 6 of this example has a substrate portion 60 and two side plate portions 61, and a pair of electrode wires so as to sandwich the substrate portion 60 between the two side plate portions 61. 21 and a pair of signal lines 31 are disposed.
Others have the same configuration and effects as the first embodiment.

(Example 5)
This example is an example of the temperature sensor 1 having an insulating holding member 6 having a substantially T-shaped cross section as shown in FIG.
As shown in the figure, the insulation holding member 6 of this example has one substrate part 60 and one side plate part 61, and a pair of signal lines 31 are arranged so as to contact the substrate part 60 and the side plate part 61. It is installed. The electrode line 21 is in contact with the signal line 31 and the substrate part 60.
Others have the same configuration and effects as the first embodiment.

(Example 6)
This example is an example of the temperature sensor 1 having an insulating holding member 6 disposed on the side of the electrode wire 21 so as to face the side surfaces of the pair of electrode wires 21 as shown in FIG.
That is, the insulating holding member 6 of this example is composed of a single flat insulating holding member 6 as shown in the figure, and is arranged in parallel to the line connecting the centers of the electrode wires 21. Further, the signal line 31 is in contact with the insulating holding member 6, and the electrode line 21 is joined to the signal line 31 on the side opposite to the side in contact with the insulating holding member 6.
Others are the same as in the first embodiment.

Also in this example, the effects of the present invention can be sufficiently exhibited, and the primary filling cement 51 can be easily and sufficiently filled between the pair of electrode wires 21.
In addition, the same effects as those of the first embodiment are obtained.

(Experimental example 1)
In this example, as shown in FIGS. 13 and 14, an impact test was performed on the temperature sensor. And the magnitude | size of the tensile stress which acted on the electrode wire 21 at this time and the quantity of the temperature sensor by which the electrode wire 21 was disconnected by the said impact test were investigated.

  In this example, samples were prepared by variously changing the site where the cement 5 was filled. As a sample E1 shown in FIG. 13 (a), a temperature sensor filled with cement 5 over the entire interior 40 of the cover 4 is used. As a sample E2 shown in FIG. A temperature sensor in which the cement 5 was filled up to the tip end surface and between the electrode wires 21 was manufactured.

  Further, as a sample E3 shown in FIG. 13C, the inside 40 of the cover 4 excluding the range between the base 210 of the electrode wire 21 to the thermistor element 2 and the connecting portion 211 between the electrode wire 21 and the signal wire 31 is provided. A temperature sensor filled with the cement 5 is used as a sample E4 shown in FIG. 13 (d) as a cement at the distal end side of the thermistor element 2 and the portion closer to the proximal end side than the connection portion 211 between the electrode wire 21 and the signal wire 31. 5 was prepared.

  Further, as a sample E5 shown in FIG. 13 (e), a temperature sensor in which cement 5 is filled in a portion closer to the base end side than the connection portion 211 between the electrode wire 21 and the signal line 31 is replaced with a sample shown in FIG. 13 (f). As E6, a temperature sensor in which the inside 40 of the cover 4 was not filled with cement was produced.

  The impact test was performed by restraining the base end side of the temperature sensor of the sample and giving an acceleration of 100 G to the temperature sensor. The acceleration of 100 G was applied in the Y direction shown in FIG. 15, which is a direction orthogonal to the line connecting the center of the electrode line 21 and the center of the electrode line 21.

The result of the impact test is shown in FIG. The numbers in parentheses in FIG. 14 are the number of samples in which the denominator has undergone the impact test, and the numerator is the number of samples in which the electrode wire 21 has been disconnected due to the impact test.
From the figure, it can be seen that for the samples E1 and E2, the tensile stress acting on the electrode wire 21 is less than 5 MPa, which is relatively small, and the electrode wire 21 is not disconnected even when an impact test is performed. On the other hand, with respect to samples E3 to E6, the tensile stress exceeds 5 MPa and is relatively large, and it can be seen that there are also samples in which the electrode wire 21 is broken by an impact test.

  13B, FIG. 13C, and FIG. 14, when comparing the sample E2 and the sample E3, it is better to dispose the primary filling cement 51 between the pair of electrode wires 21. It turns out that it is more important from the viewpoint of preventing disconnection of the electrode wire 21 than disposing the cement 5 in other parts.

(Experimental example 2)
In this example, as shown in FIG. 16 and FIG. 17, when various portions of the cement 5 are filled and vibration is applied in the X direction and the Y direction, the electrode line 21 acts in each of the X direction and the Y direction. This is an example of examining the stress. Further, the number of samples in which the electrode wire 21 was broken by the impact test was also examined.

The X direction described in the graph of FIG. 17 is a direction parallel to the direction of the line connecting the center of the polar line 21 and the center of the electrode line 21 as shown in FIG. As shown in the figure, it refers to the direction orthogonal to the X direction.
The numbers in parentheses in FIG. 17 are the number of samples in which the denominator has performed an impact test, and the numerator is the number of samples in which the electrode wire 21 is disconnected by the impact test.

  Further, in each of the two bar graphs in the X direction and the Y direction shown in FIG. 17, the left bar graph is the stress acting on the root 210 of the thermistor element 2 in the electrode line 21, and the right bar graph is the electrode of the thermistor element 2. The stress acting on the connecting portion 211 between the line 210 and the signal line 31 of the sheath pin 3 is shown.

  As the temperature sensor of this example, in addition to the sample E1 shown in FIG. 16A, the sample E2 shown in FIG. 16B, and the sample E6 shown in FIG. The following samples were prepared. That is, as the sample E7 shown in FIG. 16C, the primary filling cement 51 is filled between the electrode wires 21 like the sample E2, but the cement is not filled around the root 210 in the electrode wire 21. A temperature sensor in which the gap is formed by 0.8 mm is a sample E8 shown in FIG. 16D, and a temperature sensor in which the primary filling cement 51 is filled around the pair of electrode wires 21 is shown in FIG. As in sample E8, the primary filling cement 51 is filled between the electrode wires 21 as in the sample E8, but the gap is not filled with the primary filling cement 51 around the root 210 in the electrode wire 21. A temperature sensor having a thickness of 0.8 mm was produced.

The test results are shown in FIG.
From the figure, it can be seen that the stress acting on the electrode wires 21 of the samples E1, E2, E7, E8 is relatively small in both the X direction and the Y direction. Further, in this case, it is found that the electrode wire 21 is not broken even when the impact test is performed.
On the other hand, it can be seen from the figure that the stress acting on the electrode wires 21 of the samples E6 and E9 is large in both the X direction and the Y direction. Further, in this case, as a result of the impact test, it can be seen that the electrode wire 21 is broken.

16 and 17, when comparing sample E2 and sample E7, and sample E8 and sample E9, primary filling cement 51 is sufficiently applied to the base 210 portion of electrode wire 21 to thermistor element 2. In the case of filling, it can be seen that the stress acting on the electrode wire 21 is sufficiently reduced.
16C, FIG. 16D, and FIG. 17, comparing the sample E7 and the sample E8, it is more than the filling of the secondary filling cement 52 at the tip of the inside 40 of the cover 4. It can be seen that filling the primary filling cement 51 without forming a gap between the electrode wires 21 reduces the stress acting on the electrode wires 21.

Sectional explanatory drawing of the front-end | tip part of the temperature sensor in Example 1. FIG. AA sectional view explanatory drawing in FIG. FIG. 3 is a perspective view of an insulating holding member in Embodiment 1. Sectional explanatory drawing of the insulation holding member after being filled with the primary filling cement in Example 1. FIG. FIG. 3 is a cross-sectional explanatory view taken along line BB in FIG. 1. Sectional explanatory drawing of the temperature sensor in Example 1. FIG. In Example 1, (a) explanatory diagram showing a state where the thermistor element and the sheath pin are connected, (b) explanatory diagram showing a state before the cement is disposed around the electrode wire, (c) surrounding the electrode wire An explanatory view showing a state after the cement is disposed on (d) an explanatory view showing a state before the thermistor element, the electrode wire, the cement and the insulating holding member are inserted into the cover, and (e) the thermistor element and the electrode wire. Explanatory drawing which shows the state after inserting cement, an insulation holding member, and a cover. Explanatory drawing which shows the state of the base vicinity to the thermistor element in the electrode wire in Example 2. FIG. Sectional explanatory drawing of the temperature sensor of the direction orthogonal to an axial direction in Example 3. FIG. Sectional explanatory drawing of the temperature sensor of the direction orthogonal to an axial direction in Example 4. FIG. Sectional explanatory drawing of the temperature sensor of the direction orthogonal to an axial direction in Example 5. FIG. Sectional explanatory drawing of the temperature sensor of the direction orthogonal to an axial direction in Example 6. FIG. In Experimental Example 1, (a) a cross-sectional explanatory view of the tip end of the sample E1, (b) a cross-sectional explanatory view of the front end of the sample E2, (c) a cross-sectional explanatory view of the front end of the sample E3, (d) a sample E4 Cross-sectional explanatory drawing of a front-end | tip part, (e) Cross-sectional explanatory drawing of the front-end | tip part of the sample E5, (f) Cross-sectional explanatory drawing of the front-end | tip part of the sample E6. The test result of the impact test in Experimental Example 1. FIG. 3 is an explanatory diagram showing the vibration direction of an impact test in Example 1. In Experimental Example 2, (a) Cross-sectional explanatory diagram of the tip of sample E1, (b) Cross-sectional explanatory diagram of the tip of sample E2, (c) Cross-sectional explanatory diagram of the tip of sample E7, (d) Sample E8 Cross-sectional explanatory drawing of a front-end | tip part, (e) Cross-sectional explanatory drawing of the front-end | tip part of the sample E9, (f) Cross-sectional explanatory drawing of the front-end | tip part of the sample E6. The test result of the impact test in Experimental Example 2. Cross-sectional explanatory drawing which shows the front-end | tip part of the temperature sensor in a prior art example. The perspective explanatory drawing of the insulation holding member in a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Temperature sensor 2 Thermistor element 21 Electrode line 3 Seaspin 31 Signal line 4 Cover 5 Cement 6 Insulation holding member

Claims (11)

A thermistor element provided with a pair of electrode wires;
A sheath pin containing a pair of signal wires connected to the pair of electrode wires in a state of being exposed on the tip side,
A cover disposed at the tip so as to cover the thermistor element;
Cement arranged to connect and fix the pair of electrode wires;
A temperature sensor comprising: an insulating holding member to which the cement is fixed to hold the cement around the electrode wire.   2. The temperature sensor according to claim 1, wherein the insulating holding member has a substrate portion disposed between the pair of electrode wires.   3. The temperature sensor according to claim 2, wherein the substrate portion of the insulating holding member occupies an area of 90% or more of the space between the pair of electrode wires.   4. The space between the pair of electrode lines according to claim 2, wherein the space between the pair of electrode lines is a space formed by a portion between a root of the thermistor element and a connection portion with the signal line. Temperature sensor.   5. The temperature sensor according to claim 2, wherein the substrate portion of the insulating holding member has a thickness of 1.16 to 1.5 times the diameter of the electrode wire.   The temperature sensor according to claim 1, wherein the insulating holding member is disposed on the side of the pair of electrode wires so as to face the side surfaces of the pair of electrode wires.   The temperature sensor according to claim 1, wherein a gap formed between the insulating holding member and the thermistor element is 0.1 mm or less.   The temperature sensor according to claim 1, wherein the insulating holding member is made of alumina.   The temperature sensor according to any one of claims 1 to 8, wherein the cement is disposed so that a thickness from an outer peripheral surface of the electrode wire is 0.15 mm or less. A thermistor element provided with a pair of electrode wires, a sheath pin built in a state where a pair of signal lines connected to the pair of electrode wires are exposed on the tip side, and a tip portion so as to cover the thermistor element In manufacturing a temperature sensor having an installed cover, a cement arranged to connect the pair of electrode wires, and an insulating holding member for holding the cement around the electrode wires,
Placing the insulation holding member around the electrode wire, and placing the cement in contact with the insulation holding member and the electrode wire, a cement placement step,
A cement drying process for drying and solidifying the cement;
Thereafter, an element insertion step of inserting the integrated thermistor element, the electrode wire, the cement, and the insulating holding member into the cover is provided.   The method for manufacturing a temperature sensor according to claim 10, wherein the cement drying step is performed by holding at 150 ° C. or higher for 1 hour or longer.

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