KR102072402B1 - Temperature measurement device and method of manufacturing temperature measurement device - Google Patents

Abstract

An objective of the present invention is to provide a temperature measurement device which prevents disconnection of a temperature measurement sensor by a load such as bending and a tensile force or an impact from coal or the like fed into a silo even if a resin sheath having limitations on heat resistance or an outer protection layer of a line shape/a band shape causing high costs is not included, and obtains heat resistance while suppressing manufacturing costs by a simple structure, thus being suitable for internal temperature management of various silos. The temperature measurement device comprises: a long sheath-type temperature measurement sensor (2) having a temperature measurement unit (21) formed at a prescribed position in a long metal sheath (20); and a long support member (3) which has the sheath-type temperature measurement sensor (2) wound and attached on the outer circumferential surface (30) thereof in a helical shape in the axial direction, and supports the sheath-type temperature measurement sensor (2).

Description

TEMPERATURE MEASUREMENT DEVICE AND METHOD OF MANUFACTURING TEMPERATURE MEASUREMENT DEVICE

The present invention is a temperature measuring device suitably used in all applications in which tension is applied to a temperature measuring sensor, such as internal temperature control of various silos (storage vessels) of a steel mill or a power plant. The present invention relates to a manufacturing method thereof.

As a temperature measuring device for silos, a wire having a temperature measuring sensor such as a resistance thermometer is installed around a wire rope, and a polymer coating is applied to the outer circumference thereof. It is conventionally proposed that the upper part of the wire rope be a hook for hanging (see Patent Document 1, for example). However, in such a temperature measuring device, a low-temperature temperature measuring sensor may be easily cut off due to the impact of coal or biomass or the like, a large load during dropping, or an overall bending.

On the other hand, the structure which prevents the impact of the coal etc. which were thrown in by adding a linear or strip | belt-shaped metal material outside is also proposed (patent document 2). As a result, it is reinforced in terms of strength, and it is possible to prevent cutting of the thermocouple due to impact or tensile force. However, there is a problem that the structure becomes complicated and the manufacturing cost increases, and a problem remains that the structure is weak.

In addition, it has been proposed to coat a resin-coated thermocouple with a flexible tube, and to reinforce it by winding the wire rope around the periphery thereof as a core (patent document 3). In such a temperature measuring device, it is possible to prevent the impact from coal and the like without installing a metal material having an increased cost, and when a load is applied, the force is applied to the entire cable including the wire rope, and the strength as a whole is improved. . It is also prevented that a load is generated in the thermocouple during bending and disconnection occurs. However, since the thermocouple is provided in the shim, when the tensile force is generated in the axial direction, the share of the force on the thermocouple becomes larger than the surrounding wire rope. In addition, when a load is applied to the cable, the thermocouple may also receive a shear force from the wire rope wound around it, resulting in the thermocouple being cut as a result.

In addition, since all of the conventionally proposed resin coatings (tubes) are indispensable, there is also a problem that the responsiveness and heat resistance of the temperature measurement are limited.

Japanese Patent Laid-Open No. 63-206617 Japanese Unexamined Patent Publication No. 2009-68954 : JP-A 58-7899

Therefore, the present invention intends to solve the above-described situation, even if it does not include a resin coating which has a limit in responsiveness or heat resistance, or an outer protective layer of a linear / strip metal material that incurs high costs. Temperature measuring device suitable for internal temperature management of various silos, which can prevent disconnection of the temperature measuring sensor due to impact from coal, etc., loads such as tensile force, bending, etc., and obtain heat resistance while suppressing manufacturing cost with a simple structure. In that it provides.

This invention includes the following inventions.

(1) A long sheath type temperature measuring sensor having a temperature measuring section formed at a predetermined position inside a long metal sheath, and the sheath type temperature measuring sensor is wound in a spiral shape on an outer circumferential surface and attached to the sheath temperature. Temperature measuring device comprising a long supporting member for supporting the measuring sensor.

(2) The sheath type temperature measuring sensor is provided with a plurality of sheath type temperature measuring sensors having a temperature measuring portion formed at the tip of the metal sheath, and the position of the tip of each sensor is supported by the plurality of sheath type temperature measuring sensors. A temperature measuring device as described in (1), each of which is wound on and attached to an outer circumferential surface of the support member so as to be at different axial positions on the outer circumferential surface of the member.

(3) A plurality of sheath-type temperature measuring sensors are provided, and the plurality of sheath-type temperature measuring sensors are wound in a state where they are twisted together on the outer circumferential surface of the support member in close contact with each other (1) or The temperature measuring device described in (2).

(4) The temperature measuring device according to any one of (1) to (3), wherein the supporting member is a rope twisted by combining a plurality of element wires. Here, the "sinter wire" may be a single wire rod or a stranded wire twisted by combining a plurality of wire rods. That is to say, the term "elementary wire" includes a case of stranded wire in addition to a single wire rod.

(5) The method as described in (4), wherein the sheath type temperature measuring sensor is wound and attached in a spiral shape along the concave strand in a state of being fitted in the concave strand between the strands forming the outer surface of the support member. Temperature measuring device.

(6) The temperature measuring device according to (5), wherein the sheath type temperature measuring sensor is provided in the concave strand in a state of entering into an area inside the circumferential circle of the supporting member when viewed from a cross section.

(7) The temperature measuring device according to any one of (4) to (6), wherein the sheath type temperature measuring sensor is wound and attached in a twisted state in combination with an element wire constituting the supporting member.

(8) The temperature measuring device according to any one of (1) to (7), wherein the supporting member is composed of at least one wire rod among the wire rod made of a metal wire rod and a high strength nonmetallic fiber.

(9) A plurality of sheath-type temperature measuring sensors are provided, and the plurality of sheath-type temperature measuring sensors are formed so as to be distinguished from each other by being colored or having different shapes on the outer surface of the metal sheath. The temperature measuring device in any one of (1)-(8).

(10) A long sheath type temperature measuring sensor having a temperature measuring section formed at a predetermined position inside a long metal sheath, and the sheath type temperature measuring sensor is wound in a spiral shape along an axial direction and attached to the sheath type temperature on an outer circumferential surface thereof. A method of manufacturing a temperature measuring device comprising a long supporting member for supporting a measuring sensor, wherein the sheath-type cable before the temperature measuring part is formed is wound on the outer circumferential surface of the supporting member and then attached to the tip side of the sheath-type cable. And removing the portion from the outer circumferential surface of the support member and subjecting the portion to the temperature measurement portion to form a temperature measuring portion, and then rewinding and attaching the portion to the outer circumferential surface of the support member.

(11) The method for manufacturing the temperature measuring device described in (10), wherein a plurality of sheath type temperature measuring sensors are provided with a plurality of sheath type temperature measuring sensors provided with a temperature measuring portion at the tip of the metal sheath. After the dog is wound on the outer circumferential surface of the support member and attached, the respective ends of the different lengths of the respective sheath-type cables are separated from the outer circumferential surface of the support member, and a process of forming a temperature measuring part in each of the corresponding portions Each of the support members is wound on the outer circumferential surface of the support member and attached to the support member so that the plurality of sheath-type temperature measuring sensors have different axial positions on the outer circumferential surface of the support member. A method of manufacturing a temperature measuring device, which is wound and attached on an outer circumferential surface.

(12) The manufacturing method of the temperature measuring apparatus described in (10) or (11), wherein a plurality of sheath type temperature measuring sensors are provided, wherein the plurality of sheath type cables are closely attached to each other on the outer peripheral surface of the support member. A method of manufacturing a temperature measuring device, which is formed by winding in a state where it is twisted together.

(13) Spiral along said concave strand in the state in which the said support member is a rope twisted together by combining the several wire | wires, and the said sheath type temperature measuring sensor was fitted in the concave strand between the wire which forms the outer surface of the said support member. A method for manufacturing a temperature measuring device as described in (10) or (11), wherein the sheath cable is twisted together with an element wire constituting the support member to be wound and attached in a shape so as to be wound around the outer peripheral surface of the support member. A method of manufacturing a temperature measuring device, which is formed by winding it on.
(14) A long sheath type temperature measuring sensor having a temperature measuring portion formed at a predetermined position inside a long metal sheath, and the sheath type temperature measuring sensor is wound in a spiral shape on an outer circumferential surface and attached to the sheath temperature. A long support member for supporting a measuring sensor, wherein the support member is a rope comprising a plurality of outer circumferential side wires wound in a spiral shape on a center side wire and a circumferential surface of the center side wire. The temperature measuring sensor is wound in a spiral shape along the concave strand in a state where the temperature measuring sensor is sandwiched in the concave strand between the strands forming the outer surface of the supporting member. It is supported in the state into which it entered the inner region of the circumscribed circle of the said support member in the said recessed strand. Temperature measurement apparatus.

According to the temperature measuring device according to the present invention, since the sheath-type temperature measuring sensor made of a long metal sheath is wound and attached to the outer circumferential surface of the long supporting member in a spiral shape, the metal sheath has a temperature measuring sensor such as coal. In addition to protecting against impact, even when a tensile force occurs in the longitudinal direction, the spiral sensor side is more easily extended than the support member on the center side, thereby avoiding stress on the temperature measuring sensor, thereby preventing disconnection of the sensor. can do.

In addition, since the coil is wound in the same manner, the temperature sensor is protected by a strong metal sheath and the local sensor does not occur when the whole device is bent, so that the temperature sensor is disconnected by the bend. It can also prevent.

In addition, the temperature measuring device according to the present invention does not include an outer protective layer such as a resin coating or a linear / strip metal material, but as described above, a temperature measuring sensor when a load such as an impact, a tensile force, or a bending occurs. Since disconnection can be prevented, it can be provided with the outstanding responsiveness and heat resistance (for example, heat resistance withstanding use in the high temperature area | region of 300 degreeC-400 degreeC etc.), and is simple, and manufacture cost is simple. It can be suppressed.

In addition, a plurality of sheath type temperature measuring sensors, each having a temperature measuring portion formed at the front end of the metal sheath, are provided, and the plurality of sheath type temperature measuring sensors have different axial positions on the outer circumferential surface of the support member. When each of the temperature measuring sensors is wound around and attached to the outer peripheral surface of the supporting member, the respective temperature measuring sensors are simply wound around the supporting member and attached to each other, so that they are securely placed on the outer peripheral surface of the supporting member without interfering with each other. It is possible to provide a temperature measuring sensor capable of controlling temperature at different axial positions as an efficient and stable quality.

In addition, a plurality of sheath-type temperature measuring sensors are provided, and in the state where the plurality of sheath-type temperature measuring sensors are wound in a state where they are twisted together on the outer circumferential surface of the support member in close contact with each other, each of them is supported by each other. The temperature sensor is supported in a stable state on the support member, and for example, excessive stress is applied to each temperature sensor even when subjected to impact or tensile force from coal, etc., which is used when used for temperature control in a silo. The disconnection of a sensor can be prevented more reliably.

The support member is a rope twisted by combining a plurality of wires, and the sheath type temperature measuring sensor is wound in a spiral shape along the concave strands while being sandwiched in the concave strands between the wires forming the outer surface of the support member. Even when attached, each temperature measuring sensor is supported in a stable state inside the concave strand on the support member, and for example, even when subjected to impact or tensile force from coal, etc. used when used for temperature control in a silo, Excessive stress on the temperature measuring sensor can be avoided, so that disconnection of the sensor can be more reliably prevented. In particular, when the sheath type temperature measuring sensor is installed in the concave strand in a state where it enters the inner region of the circumferential circle of the supporting member, the temperature measuring sensor itself is less likely to receive the impact or the tensile force from the beginning. This can prevent the disconnection of the sensor more reliably.

In addition, when the sheath-type temperature measuring sensor is wound and attached in a twisted state in combination with the element wire constituting the supporting member, even if the temperature measuring sensor is supported in a more stable state on the supporting member, Excessive stress on the temperature measuring sensor can be avoided, thereby more reliably preventing disconnection of the sensor. In addition, since the temperature measuring sensor is disposed and installed on the support member at the same time as the manufacture of the support member, the manufacturing is remarkably efficient and the manufacturing cost can be significantly reduced.

In addition, a plurality of sheath-type temperature measuring sensors are provided, and the plurality of sheath-type temperature measuring sensors have different colors or different shapes on the outer surface of the metal sheath, so that they can be distinguished from each other. The combination of the measuring device and the proximal terminal connected to the measuring device can be easily determined, thereby improving workability and preventing wiring mistakes.

In addition, as a manufacturing method of these temperature measuring apparatuses, the sheath cable before the temperature measuring part is formed is wound on the outer circumferential surface of the support member, and then the front end side portion of the sheath cable is detached from the outer circumferential surface of the support member. After the process of forming the temperature measuring part on the site, the manufacturing method of rewinding and attaching again on the outer peripheral surface of the support member, in comparison with the case of winding the temperature measuring sensor formed with the temperature measuring part on the supporting member The process of sticking can be performed reliably and efficiently, manufacturing cost can be reduced, and quality is also stable.

1 is an explanatory diagram showing a temperature measuring device according to a typical embodiment (first embodiment) of the present invention.
Fig. 2 is an explanatory diagram showing a sheath type temperature measuring sensor constituting the same temperature measuring device.
3 is an explanatory diagram showing a main portion of the same temperature measuring device.
4 is an overall configuration diagram showing the same temperature measuring device.
5 is an explanatory diagram showing a manufacturing method of the same temperature measuring device.
6 is an explanatory diagram showing the same manufacturing method.
7 is an explanatory diagram showing a temperature measuring device according to another embodiment (second embodiment) of the present invention.
8 is an explanatory diagram showing a main portion of the same temperature measuring device.
9 is a sectional view showing the same temperature measuring device.

EMBODIMENT OF THE INVENTION Next, embodiment of this invention is described in detail based on an accompanying drawing.

The temperature measuring apparatus 1 which concerns on typical embodiment (1st Embodiment) of this invention is a long sheath type temperature measuring sensor (as shown to FIG. 1 thru | or 3) ( 2) and the sheath type temperature measuring sensor 2 is attached to the outer circumferential surface 30 in a spiral shape along the axial direction and is formed of a long supporting member 3 supporting the sheath type temperature measuring sensor 2. For example, it is for hanging the inside of various silos of a steel mill or a power plant, and for temperature control in a silo by the temperature measuring sensor 2. As shown in FIG.

The supporting member 3 is a long member which consists of metal wire rods, bars, wire ropes, etc. which support the load of the temperature measuring sensor 2, and has sufficient tensile strength. The shape of the cross section is not particularly limited. In addition to the metal, it may be made of other materials such as high strength nonmetallic fibers.

The base end side of the supporting member 3 is bent in a loop shape to form an attachment portion 4 which is fixed by caulking by a metal tube 40 and fixed to the upper side of the silo, not shown. By being attached to the hanging portion, the supporting member 3 is supported in a state where the front end is put into the silo. The temperature measuring sensor 2 is supported by being suspended by the support member 3 in the silo by being wound in a spiral shape on the outer circumferential surface of the support member 3 suspended in the silo.

The temperature measuring sensor 2 has a temperature measuring part 21 formed at a predetermined position inside the elongated metal sheath 20, and in this example, a pair of thermocouple wires inside the metal sheath 20. 22 is provided, and a hot junction in which a thermocouple element wire is connected as a temperature measuring section 21 is formed at the tip end, and an inorganic insulating powder such as magnesia (MgO) is formed in the gap inside. (23) is a sheathed thermocouple filled. A sheath thermocouple provided with two or more pairs of thermocouple wires may be used. In addition, it is not limited to this sheath thermocouple at all, Other temperature measuring sensors, such as a sheath resistance thermometer, may be sufficient.

Since the metal sheath 20 of the temperature measuring sensor 2 has heat resistance, in the case where the support member 3 is a metal material such as steel wire, plated steel wire, stainless steel wire or the like, For example, it can be used in a temperature atmosphere over 300 ℃. In addition, when the support member 3 is made of stainless steel or a high strength nonmetallic wire such as carbon fiber or aramid fiber, and the metal sheath 20 is made of stainless steel, the support member 3 has excellent corrosion resistance and can be used in a corrosive atmosphere. You can do that.

In the present embodiment, a plurality of (six) sheath-type temperature measuring sensors 2 are wound in a state where they are twisted together on the outer circumferential surface of the supporting member 3 in a state of being in close contact with each other. These sheath-type temperature measuring sensors are respectively wound and attached on the outer peripheral surface of the supporting member 3 so that the position of the tip of each sensor may be a different axial position on the outer peripheral surface of the supporting member 3. Thereby, the position of the temperature measuring part 21 of each sensor is also arrange | positioned in a different position in an axial direction, respectively, and is comprised so that the temperature of the different height position (six places) in a silo can be measured.

The sheath type temperature measuring sensor 2 wound on the outer circumferential surface of the supporting member 3 is fixed on the outer circumferential surface of the supporting member 3 by a seeding 5 at a suitable place so as to maintain the wound state without disturbing the wound state. have. The seeding 5 is made of a fine metal wire made of stainless steel that binds and fixes the temperature measuring sensor 2 on the outer circumferential surface of the support member 3, but may be a clip or the like. It is also possible to fix with a heat resistant adhesive or the like.

4 is an overall configuration diagram of the temperature measuring sensor 2. The proximal end of the sheath type temperature measuring sensor 2 extending from the proximal end of the supporting member 3 is connected to and connected to a lead wire 24 connected to a measuring device not shown in the drawing. Here, it is preferable that the outer surface of the metal sheath of the plurality of sheath-type temperature measuring sensors is colored in different colors or in different shapes. As a result, the combination between the measuring device and the terminal 25 on the proximal end connected thereto can be easily determined, thereby improving workability and preventing wiring mistakes.

Next, the manufacturing procedure of the temperature measuring apparatus 1 which concerns on this embodiment is demonstrated based on FIG. 5 and FIG.

First, as shown in Fig. 5A, a sheath-type cable in which a thermocouple wire 22 is built into the metal sheath 20 before the temperature measuring part is formed, and the inorganic insulating powder 23 is filled in the gap ( 6) A plurality (6 in this example) is wound on the outer circumferential surface of the support member 3 and attached. The sheath-type cable 6 is wound on the outer circumferential surface of the supporting member 3 in a state of being in close contact with each other and wound and attached.

It is preferable that the seeding 5 is provided at the end of the sheath cable so that the wound sheath cable 6 is not scattered. And cut the length required as a temperature measuring device.

Next, as shown in Figs. 5B to 5G, the front end side portions of the sheath cable 6 are sequentially removed from the outer circumferential surface of the support member 3, thereby forming a temperature measuring section. After carrying out, the work is again wound on the outer circumferential surface of the support member 3 and fixed by the seeding 5. In other words, the tip side portion is removed by the length necessary for the processing of the temperature measuring unit, and then wound and reattached after the processing. Accordingly, the sheath type temperature measuring sensor 2 is configured.

The temperature measuring part is located on the proximal side of the support member 3 in order to remove it, to process and rewind the temperature measuring part, and the processed temperature measuring sensor 2 is sequentially seeded from the proximal end. 5) to be fixed. As a result, as shown in Fig. 5 (h), a plurality of six sheath-type temperature measuring sensors 2 have different axes on the outer circumferential surface of the support member 3 in the position of the tip of each sensor. It is constituted by being wound and attached on the outer circumferential surface of the support member 3 to be in the directional position.

The processing of the temperature measuring part in each sheath-type cable 6 is first carried out by the sheath-type cable 6 removed from the support member 3 as shown in Figs. 6A to 6B. ) Is further cut to a predetermined length, and a temperature measuring portion is formed at the tip portion thereof as shown in Figs. 6C to 6D. More specifically, the front end side portion of the sheathed cable 6 is sandwiched by the support jig for processing 7 with the opening facing upward, and the inorganic insulating powder 23 is removed in this state. The temperature measurement part 21 is formed in the front-end | tip in accordance with the order of the thermal contact processing in manufacture of a well-known sheath thermocouple, such as a wire connection, a welding rod, etc.

The temperature measuring sensor 2 having the temperature measuring part 21 is wound on the outer circumferential surface of the supporting member 3 again, as shown in Figs. 6E to 6F, and is attached so as not to scatter. It is fixed by).

As described above, in the temperature measuring sensor 2 of the present embodiment, after winding the sheath-type cable 6 around the support member 3, the temperature measuring part 21 is processed at the tip while unwinding and adjusting the length one by one. The temperature measuring device of the present invention is not limited to this, but a plurality of temperature measuring sensors having different lengths in which the temperature measuring part has been processed at the front end in advance are manufactured. The dogs may be prepared, and they may be formed by winding them in a spiral shape on the outer circumferential surface of the support member 3.

Next, another embodiment (second embodiment) of the present invention will be described with reference to Figs.

In this embodiment, the support member 3 is a wire rope twisted by combining the plurality of wire strands 31, 33, and 34, and the sheath type temperature measuring sensor 2 forms the outer surface of the support member 3. It is wound in a spiral shape along the concave strand 32 in a state of being sandwiched in the concave strand 32 between the element wires 31 which are being made. One wire strand 31 may be a single hard wire (wire), or may be a thin rope twisted together by joining a plurality of hard wires (wire). In addition, a single hard wire (wire) may be used for each of the one wire element 33 and one wire element 34, or may be a thin rope (twisted wire) twisted together by combining a plurality of wire elements (wire).

In more detail, as shown in FIG. 9, the sheath type temperature measuring sensor 2 is installed in the concave strand 32 in the state in which it entered the inner region of the circumferential circle 35 of the support member 3 when viewed from a cross section. Therefore, the temperature measuring sensor 2 is less likely to be subjected to impact or tensile force from coal or the like injected into the silo, and has a structure capable of more reliably preventing disconnection.

In this example, nine temperature measuring sensors 2 are wound and attached to measure the internal temperature of nine height positions in the silo, and thus the temperature measuring sensor 2 is placed on the outer circumferential surface 30 of the supporting member 3. The concave strands 32 in the form of spirals for sandwiching are formed in at least nine (nine equal numbers in this example). The number of concave strands 32 is determined by the number of wire strands 31 of the outermost layer forming the outer surface of the support member 3.

Therefore, according to the number of the temperature measuring sensors 2, it is determined so that the number of element wires of the outermost layer of the support member 3 may be more than that. It is preferable that the wire strands 31, 33, 34 and the temperature measuring sensor (sheath-type cable) constituting the support member 3 are simultaneously twisted together and manufactured. In this case, in terms of balance, it is preferable to match the number of wire strands of the outermost layer with the number of temperature measuring sensors.

Since structures other than this, a manufacturing procedure, these modifications, etc. are the same as the typical embodiment (1st Embodiment) demonstrated above, the same code | symbol is attached | subjected about the same structure, and the description is abbreviate | omitted.

As mentioned above, although embodiment of this invention was described, this invention is not limited to these Examples at all, Of course, it can be implemented in various forms in the range which does not deviate from the summary of this invention.

1: temperature measuring device
2: temperature measuring sensor
3: support member
4: Attachment part
5: seeding
6: sheath type cable
7: jig for support
20: metal sheath
21: temperature measuring unit
22: thermocouple element wire
23: inorganic insulation powder
24: lead wire
25 terminal
30: outer circumference
31 wire wire
32: concave strand
35: circumscribed circle
40 metal tube

Claims (8)

A long sheath sheath type temperature measuring sensor having a temperature measuring section formed at a predetermined position inside a long metal sheath,
The sheath-type temperature measuring sensor is wound on the outer circumference in a spiral shape and attached to the long supporting member for supporting the sheath-type temperature measuring sensor.
Done,
The support member is a rope composed of a plurality of outer circumferential side wires wound in a spiral shape on the center side wire and the outer circumferential surface of the center side wire , and the sheath type temperature measuring sensor is an outer surface of the support member. In the state sandwiched between the concave strands forming the wires, wound along the concave strands are attached in a spiral shape,
The sheath type temperature measuring sensor is supported in a state where it enters the inner region of the circumscribed circle of the support member in the concave strand when viewed in cross section.
Temperature measuring device, characterized in that.
The method of claim 1,
As said sheath type temperature measuring sensor, the sheath type temperature measuring sensor in which the temperature measuring part was formed in the front-end | tip of a metal sheath is provided in multiple numbers,
In addition, these sheath type temperature measuring sensors are each wound and attached on the outer peripheral surface of the said support member so that the position of the front end of each sensor may be a different axial position on the outer peripheral surface of the said support member.
Temperature measuring device.
The method according to claim 1 or 2,
And the sheath-type temperature measuring sensor is wound and attached in a twisted state in combination with an element wire constituting the supporting member.
The method according to claim 1 or 2,
A temperature measuring device in which said supporting member is composed of at least one wire rod of a wire rod made of a metal wire rod and a high strength nonmetallic fiber.
The method according to claim 1 or 2,
A plurality of sheath type temperature measuring sensors are installed,
These sheath type temperature measuring sensors have different colors or different shapes on the outer surface of the metal sheath and are configured to be distinguished from each other.
Temperature measuring device.
A method of manufacturing the temperature measuring device according to claim 1 or 2,
After winding the sheath-type cable before the temperature measuring part is formed on the outer peripheral surface of the support member,
The front end side part of the sheath cable is detached from the outer peripheral surface of the support member,
After the process of forming a temperature measuring part in the site,
Winding again on the outer peripheral surface of the support member
Method for producing a temperature measuring device, characterized in that.
A method for manufacturing the temperature measuring device according to claim 6, wherein the sheath type temperature measuring sensor is provided with a plurality of sheath type temperature measuring sensors having a temperature measuring portion formed at the tip of the metal sheath.
After winding the plurality of sheath-type cables on the outer peripheral surface of the support member,
The front end side portions of different lengths of the respective sheathed cables are separated from the outer peripheral surface of the support member,
After the process of forming a temperature measuring part in each said site | part,
Rewind and attach to the outer peripheral surface of each of the support member,
Thus, a plurality of sheath-type temperature measuring sensors are manufactured by being wound on and attached to the outer circumferential surface of the support member such that the position of the tip of each sensor is a different axial position on the outer circumferential surface of the support member. Way.
A method of manufacturing the temperature measuring device of claim 6,
A method for manufacturing a temperature measuring device, wherein the sheath-type cable is twisted together with an element wire constituting the support member to be wound and attached onto an outer circumferential surface of the support member.

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