JP2008151601A - Platinum temperature measuring resistor with element and insulating resin having the same diameter, and manufacturing method therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize an ultrafine type platinum temperature measuring resistor with a platinum resistance element being exposed, which is excellent in responsibility and can measure a temperature precisely, and realize a manufacturing method therefor. <P>SOLUTION: The platinum resistance element made up by placing a platinum wire in a ceramic body is inserted into an ultrafine stainless protecting tube having an inside diameter approximately identical to an outside diameter of the element, and a resin is injected into the stainless protecting tube on the side having a lead wire, while performing a vacuum operation, and after curing of the resin, the stainless protecting tube is immersed in a solvent, thereby dissolving and removing a stainless portion. Therefore, the lead wire is molded by the resin so as to be in a cylindrical form having the outside diameter identical to that of the platinum resistance element, and the element co-diameter type platinum temperature measuring resistor having a lead wire section which is integrated with the platinum resistance element body, is obtained. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an extremely fine platinum resistance thermometer with excellent productivity and a method for manufacturing the same, which can increase the thermal response (response) and perform precise temperature measurement.

  Currently, in addition to those using platinum resistance, those using thermocouples, thermistors, IC sensors, etc. are also used for industrial temperature measurement. Of these, those using platinum resistance are subject to secular change. On the other hand, it is stable, has the highest stability, and is accurate. Therefore, it is often used for measurement of precision temperature that requires high accuracy.

  The reason why platinum is used in thermometers is that the accuracy is significantly better than thermocouples, thermistors, IC sensors, glass thermometers, etc., and the resistance change due to temperature changes is excellent in linearity. This is because it is defined in the scale (ITS-90).

  These temperature sensor devices are used in various environments, and may be used in an environment where they are hardly subjected to vibration or impact, and conversely, they may be used in an environment where vibration or impact is strong. Moreover, heat resistance, chemical resistance, and corrosion resistance may be required.

  Under such circumstances, the resistance element for temperature measurement is rarely used alone, and is generally used as a resistance temperature element incorporated in a protective tube. Depending on the application, it may be used as a resistance temperature detector coated with a resin.

  As an example of the resistance temperature detector incorporated in the protective tube, there is one of Patent Document 1 (Japanese Patent Laid-Open No. 11-195501), and its configuration is shown in FIG. A platinum or platinum rhodium wire is used as the resistance wire, and a resistance temperature detector 22 having a lead wire 25 welded to the resistance wire is inserted into a protective tube 23 whose one end is sealed, and the temperature measurement device described above. A high temperature thermometer 21 having a configuration in which powder 24 is filled around a resistance element 22 and fixed in a protective tube 23 is shown. Since the temperature measuring resistance element 22 of the temperature measuring section is compactly built with a powder 24 mainly composed of alumina in the protective tube 23 without a gap, it has a structure resistant to vibration and impact.

  Further, when a platinum resistance thermometer is used, the lead wire resistance cannot be ignored, but in order to avoid errors due to the lead wire resistance, a three-wire connection is often used. Furthermore, when high accuracy is required, a 4-wire system is also used, and the 4-wire system can remove errors almost completely.

  Such a thing is shown by patent document 2 (Registered Utility Model No. 3060490). This is an element body having one or more thin metal wires for resistance temperature detectors inside, and each pair of element leads corresponding to each thin metal wire drawn from one end of the element body A platinum resistance thermometer element composed of a wire is provided, and a temperature detection signal is sent to the outside through a lead wire connected to each element lead wire. And, as a configuration for reinforcing the connecting portion in response to vibration and shock of the connecting portion between the lead wire and the lead wire, at least from the middle of the element body on the side where each element lead wire is drawn out, Using the heat shrinkability of the first resin and the second resin, the double structure of the first resin and the second resin up to the portion beyond the joint portion between the element lead wire and the corresponding lead wire lead It is set as the structure coat | covered with no gas part. What was constituted in this way is inserted in a case, and is filled with a filler after that. As described above, since the junction between the resistance temperature detector element and the lead wire is molded without a gas portion, even if it is used in a bad environment where vibration and impact are strong, disconnection does not occur. The state in which the temperature can be measured can always be maintained.

  In the above-mentioned Patent Document 2, a three-wire connection is shown, and it is also described that a four-wire connection can be made.

  As an example of what is coated with resin, as shown in Patent Document 3 (Japanese Utility Model Laid-Open No. 1-112432), a platinum resistance element and a lead wire are embedded in a covering material made of PFA resin and PTFE resin. Some molded structures have excellent chemical resistance, corrosion resistance, and heat resistance.

As the platinum resistance thermometer element used for the platinum resistance thermometer as described above, for example, one as shown in the specification of Patent Document 4 (Japanese Utility Model Publication No. 57-126035) can be used. A protective tube made of ceramic provided with an insertion hole, and a lead wire and a resistance wire are inserted into the insertion hole, and the resistance wire and the lead wire are connected on the side opposite to the lead-out direction of the lead wire, and the resistance The connection portion between the wire and the lead wire is sealed and fixed to the end portion of the protective tube with a coloring agent.

JP-A-11-195501 Registered Utility Model No. 3060490 Japanese Utility Model Publication No. 01-112432 Japanese Utility Model Publication No.57-126035

  Temperature sensor devices used for industrial use are often used under adverse conditions different from usual. Therefore, there is a need for a temperature sensor device that can always maintain a state in which a precise temperature can be measured even in an adverse environment where vibration and impact are strong.

  In general, the performance required for the temperature sensor device is that the specified electrical performance is stable in the measurement temperature range, that it is as small and lightweight as possible, that it has excellent thermal responsiveness, and that vibration and It has sufficient mechanical strength against impacts and the like, and further has excellent chemical resistance.

  Therefore, practically, the resistance element for temperature measurement is not used as it is, but is used as a resistance temperature element incorporated in the outer sheath of a protective tube, etc. It was compatible with vibration, shock and other external environments. The above-described conventional temperature sensor device is also configured in consideration of a bad environment where vibration and impact are strong by using a protective tube and a covering material.

  However, even when the resistance element for temperature measurement itself and the resistance element assembled as a resistance temperature detector are used, the performance obtained by the presence of an outer coating such as a protective tube is different. For example, by using an outer coating, the heat transfer time from the temperature measurement target part to the temperature measurement sensor unit is delayed, and the heat capacity of the temperature measurement sensor unit is increased, resulting in a delay in the thermal response as the temperature measurement sensor. It was supposed to be.

  Thus, the not touch the absolutely measurement object directly element because the element has not been exposed directly, that the response in indirect that heat touch via the exterior of the device becomes slow problem It was.

  On the other hand, platinum resistance thermometers are generally used for low-temperature measurement and have higher accuracy than thermocouples. However, it is considered unsuitable for the case where quick responsiveness is required or measurement of the surface and minute portions. This is because the platinum resistance temperature detector has a considerable volume as a resistance element, so that the time until it reaches thermal equilibrium is longer than that of the thermocouple type temperature sensor. Therefore, it is required that the temperature sensor part of the platinum resistance thermometer is as small as possible to reduce the heat capacity.

  Therefore, an object of the present invention is to obtain a resistance thermometer having a good thermal response and a very thin resistor that does not use an outer coating such as a protective tube that is robust and does not vary in size. It is to realize a simple manufacturing method capable of obtaining a body with a high yield.

  In the invention of the present application, the outer covering such as the protective tube of the platinum resistance thermometer element having reduced thermal responsiveness is not used, and the connecting portion of the lead wire is covered with the same diameter as the element portion with the element portion exposed. An element having an integral structure in which an element main body and a lead wire mold part are continuously integrated and an insulating resin same-diameter platinum resistance thermometer (hereinafter referred to as an "element equivalent-diameter platinum resistance thermometer"). The present invention intends to realize a method of manufacturing a platinum resistance temperature detector having the same element diameter. Here, the same-diameter platinum resistance thermometer of the element and insulating resin (element equal-diameter platinum resistance thermometer) is a resistance temperature detector whose outer diameter of the platinum resistance thermometer body is used over the entire length. A platinum resistance thermometer having the same outer diameter as that of the element.

The object of the present invention can be realized by the following configuration.
(1) A platinum resistance thermometer element comprising a cylindrical platinum resistance thermometer element body having a platinum resistance member for temperature measurement inside and a plurality of element lead wires led out from one end of the element body. A platinum resistance thermometer that sends a temperature detection signal to the outside via lead wires respectively connected to the element lead wires, and leads corresponding to the element lead wires from one end of the element body. The part beyond the joint part with the wire is formed by molding with resin in a cylindrical shape having the same diameter as the outer diameter of the element body.

(2) A resistance temperature measuring element comprising a cylindrical element body having a resistance member for temperature measurement inside and a plurality of lead wires led out from one end of the element body is connected to the outer diameter of the element body. And insert the resin into the metal tube on the side with the lead wire while evacuating the resin. After curing the resin, immerse the metal tube in a solvent. The metal tube is configured to be dissolved and removed.

(3) A lead wire is connected to each element lead wire of the platinum resistance thermometer element in which a plurality of element lead wires are led out from one end, and the platinum resistance thermometer element connected to the lead wire is connected to the outer diameter of the element body. And insert the resin into the stainless steel tube on the side with the lead wire while evacuating the resin. After hardening the resin, immerse the stainless steel tube in the solvent. The lead wire is sealed with a resin having an outer diameter equal to the outer diameter of the platinum resistance thermometer element body by dissolving and removing the stainless steel tube, and the lead wire portion is the platinum resistance thermometer An element same-diameter platinum resistance thermometer integrated with the element body is manufactured.

  The element equal-diameter platinum resistance temperature detector according to claim 1 of the present invention is capable of reducing the heat capacity because the measurement part of the element is bare and does not have an outer coating, and has a fast thermal response and an epoxy resin. Since almost completely insulating material is used, there is no problem of insulation deterioration (defect), and precise measurement is possible. In addition, the resistance thermometer can be made thin because it does not have an outer coating, and it becomes possible to measure the temperature of a minute part. Also, the element body and the epoxy resin are completely bonded, so that it breaks in strength. There is no problem, and since the outer tube protection tube is not used, it can be used for bending, thus further expanding the range of usable locations.

  Furthermore, since the element main body and the insulating portion of the epoxy resin portion have the same diameter, it is advantageous that the insertion into the temperature measuring hole (hole) can be performed smoothly. For example, when there is a step between the element body and the insulator of the epoxy resin part, the epoxy resin part is usually thicker. For this reason, it is necessary to make the temperature measuring hole according to the thickness of the epoxy resin. In such a case, an air layer is generated because a gap is generated between the element and the temperature measuring hole. In that case, since heat is not transmitted to the element which is the temperature sensing portion, the thermal responsiveness is deteriorated, so that the measurement conditions are not good.

  According to the method of manufacturing a platinum resistance thermometer according to claims 2 to 3 of the present invention, insulation processing having the same diameter as the platinum resistance thermometer element is possible, and the element is not exposed and the element is not exposed. The biggest feature is that it can be processed. Since the metal tube can be processed precisely, the resistance temperature detector having an outer shape corresponding to the inner surface shape of the metal tube also has a precise and uniform outer shape, so that the products can be made uniform. Further, since the metal tube is removed not by mechanical removal but by chemical treatment, even an extremely fine resistance temperature detector can be manufactured without damage. Furthermore, since the epoxy resin is filled while degassing under vacuum, a defective product due to residual air does not occur. Furthermore, in the invention of claim 3, since stainless steel is used as the metal tube, the stainless steel protective tube used for the resistance temperature detector with the protective tube can be used, which is advantageous in terms of cost.

  With the further development of technology in the industry, it is desired to supply thermometers with two beats: (1) fast response and (2) high accuracy in the field of temperature measurement and control. In addition, awareness of the importance of temperature management and measurement is increasing in order to stabilize quality. For example, companies such as national and private research institutes, semiconductors, biotechnology, automobiles (automobile parts), electronic parts, precision measuring instrument products, food, medical equipment, pharmaceuticals, electronics, chemistry, etc. Response and accuracy are required in the field of temperature management, measurement, and control.

  Since the element equal-diameter platinum resistance temperature detector of the present invention has the above two conditions, it is used to satisfy the requirements of the above fields.

  Hereinafter, the element equal-diameter platinum resistance temperature detector and the manufacturing method thereof according to the present invention will be described with reference to the drawings.

  FIG. 1A is an overall view of an element same-diameter platinum resistance temperature detector according to the present invention, and FIG. 1B is a cross-sectional view thereof. FIG. 2 is a diagram showing the manufacturing process, and FIG. 3 is a diagram for explaining each manufacturing process.

1. Configuration of Element Same Diameter Type Platinum Resistance Temperature Sensor The configuration of the element same diameter type platinum resistance temperature detector of the present invention will be described with reference to FIGS. 1 (a) and 1 (b). FIG. 1A is an external view of an element equal-diameter platinum resistance temperature detector of the present invention, and FIG. 1B is a sectional view in the length direction. In FIG. 1 (a), 1 is a platinum resistance temperature detector of the present invention, 2 is a platinum resistance thermometer element body, 3 is a resin mold, 4 is a lead wire, and in FIG. Is a ceramic wire, 6 is a resistance wire for temperature measurement such as platinum wire, 7 is an element lead wire welded to the resistance wire, 8 is a filler, 9 is a cement for sealing the head of the resistance wire, 10 is a lead wire Cement for sealing the lead-out portion of the wire, and 11 is an insulating coating material for the element conductor portion.

  With such a configuration, the resistance wire 6 made of platinum or the like is wound in a coil shape, and one end portion thereof is bent to form a U-shape as a whole and is inserted through the through hole of the ceramic body 5. 7 is welded. In the through hole of the ceramic body 5, an insulating material 8 of special powder is filled, and the platinum resistance wire 6 is stably held. The exposed portion of the platinum resistance wire on the head side of the element body 2 is sealed with cement 9, and the lead-out portion of the element lead-out wire on the rear end side is sealed with cement 10.

  The lead wire 4 made of nickel or the like is welded to the element lead wire 7 of the platinum wire, and is molded and insulated with a resin 3 such as epoxy for a predetermined length beyond the welded portion of the element lead wire from the rear end of the element body. Has been. An exposed portion of the lead wire 4 from the resin mold is used as a lead wire for signal output of the resistance temperature detector 1. The resin mold part 3 of the conducting wire is formed in a cylindrical shape having the same diameter as the outer diameter of the element body, and the epoxy resin and the cement at the rear end part of the element are bonded to form the element body 2 and the molding part 3 of the conducting wire. The element is continuously integrated and constitutes the element same-diameter platinum resistance temperature detector 1.

  Three lead wires may be connected when the resistor is used as a three-wire type, and four when connected as a four-wire type.

2. Method for Manufacturing Element Same Diameter Platinum Resistance Temperature Sensor An example of a method for manufacturing an element equal diameter platinum resistance thermometer of the present invention will be described for each step with reference to FIGS.

(1) Step 1—A platinum resistance thermometer element is inserted into a stainless steel tube.
A case where a stainless steel tube is used as the metal tube will be described. What is shown in FIG. 3 (a) is a platinum resistance thermometer element before being inserted into a stainless steel pipe (hereinafter referred to as SUS pipe), and a lead wire such as nickel is welded to the lead wire of the platinum resistance thermometer element, Up to a predetermined portion of the element lead wire beyond the welded portion 12 is covered with a polyimide tube 11 for insulation. In addition, it is desirable that the conductive wire is also subjected to insulation treatment at portions other than the welded portion. The platinum resistance thermometer element thus treated is inserted into the SUS tube. The inserted one is shown in FIG. The SUS tube used has an inner diameter that is substantially equal to the outer diameter of the platinum resistance thermometer element, so that the resin does not enter the gap between the elements when the element is inserted into the SUS pipe.

(2) Step 2—Resin is injected from the opening of the stainless steel tube while evacuating.
Next, the epoxy resin is filled into the SUS tube, and the filling operation is performed while degassing in a vacuum (vacuum desiccator) that draws a vacuum so that air does not enter during filling. In step 1, an epoxy resin is injected through the resin injection tube from the lead wire side opening of the SUS tube in which the platinum resistance thermometer element is inserted. At this time, if the operation is not performed while defoaming, an air layer is generated in the SUS tube, causing problems such as a decrease in response and poor insulation. In addition, the epoxy resin having a fine particle is selected and the thermosetting type is used. In order to fill the epoxy resin in the vacuum apparatus, the temperature in the apparatus is appropriately increased and set to an appropriate temperature at which the epoxy resin softens. By doing so, the epoxy resin can be completely filled in the SUS tube without an air layer. This work is an important work for obtaining complete insulation when completed.

  This filling operation can also be performed while sucking the air in the SUS tube with a vacuum device. At that time, if both ends of the SUS tube are open, the other end opening while sucking air through the gap between the inner wall of the metal tube and the outer wall of the resistance element from the opening on the leading side of the platinum resistance thermometer The resin is injected so as to close the opening. At this time, since the gap is very small, air can pass through but resin does not enter.

  Also, when the element head side of the metal tube is closed (left dotted line in FIG. 3B), a suction thin tube is inserted from the lead wire side opening to the element conductor lead-out portion of the element body. Then, the resin is injected so as to block the opening from the opening while sucking the air inside through the thin tube, and the capillary is pulled out when the injection is completed.

(3) Step 3—The resin is cured.
After the resin has been injected, heat treatment is performed to cure the resin. The cured state is shown in FIG.

(4) Step 4-A stainless steel tube is dissolved in a solvent.
Next, an operation for melting the SUS tube is performed. By inserting an element into the SUS tube, injecting a resin, and leaving the cured resin in a ferric chloride solution for several hours, the SUS tube is melted away and only the internal one remains. Here, the platinum resistance temperature detector in which the platinum resistance thermometer element and the epoxy resin are integrated is extremely fine and has the same diameter over the entire length.

  Since the internal epoxy resin and the SUS pipe are bonded, it is impossible to mechanically pull out from the SUS pipe so as not to break. Therefore, by removing the SUS tube by chemical treatment as described above, the platinum resistance temperature detector inside can be taken out without being damaged.

(5) Step 5: The stainless steel tube is removed, and the resistance temperature detector in which the lead wire is sealed integrally with the resistance temperature sensor with a resin is taken out.
The resulting product is a platinum resistance thermometer having an insulator with the same diameter as the element body. The completed product is as shown in FIG.

  In an example of actual manufacturing, a stainless steel tube having an outer diameter of Φ0.5 mm and an inner diameter of Φ0.4 mm is used, and a resistance temperature measuring element having an outer diameter of Φ0.4 mm and a total length of the element body of 3 mm (our company Using a platinum resistance thermometer resistance element Plastic-MC type MC-0403) manufactured by Nethshin), an outer diameter Φ of 0.4 mm and a total length of the resistor body portion of 15 mm were obtained.

  The feature of this manufacturing method is that, if this manufacturing method is used, it is possible to manufacture a thermometer resistance element of any thickness regardless of the outer diameter of the resistance thermometer element by using a metal tube with an appropriate inner diameter. Become. For example, regarding our products, any of platinum resistance thermometer elements (Plastic-MC type series from Netshin Co., Ltd.) whose outer diameter Φ is 1.6 mm, 1.2 mm, 0.8 mm, and 0.4 mm. The present invention can be carried out by using a metal tube having an appropriate inner diameter even for those having an outer diameter of.

  Moreover, if the manufacturing method of this invention is used, as long as there is a solvent which dissolves a metal tube other than a SUS tube, it can be manufactured. For example, when a copper tube other than SUS is used, a strong acid solvent such as nitric acid may be used as the solvent. Also, the length can be manufactured from long to short, practically from several times to several tens of times the length of the resistance element body, or more.

  Further, the manufacturing method of the present invention can be applied to a resistance temperature sensor other than a platinum resistance temperature sensor element as long as it has an element conductor at one end of a cylindrical element body. Production with a thermometer using a thermocouple or thermistor other than the platinum resistance thermometer can also be produced using this production method.

  With the manufacturing method of the present invention, it has excellent operability comparable to that using a conventional protective tube, but the thermal response is remarkably excellent, and a robust and fine resistance temperature detector can be manufactured. In this field and temperature measurement of fine parts, it is possible to expect a wider range of industrial use than conventional ones.

  Moreover, since it can manufacture using this manufacturing method also about the manufacture with the thermometer using thermocouples and thermistors other than a platinum resistance thermometer, the possibility of utilization in a wider field | area is anticipated.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. It is a figure which shows the manufacturing process of the element equal diameter type platinum resistance temperature detector of this invention. It is a figure explaining each manufacturing process of the element equal diameter type platinum resistance temperature detector of this invention. It is a figure which shows the conventional platinum resistance thermometer with a protective tube.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Element same diameter type platinum resistance thermometer 2 Platinum resistance thermometer resistance element body 3 Resin coating material 4 Lead wire 5 Ceramic body 6 Platinum resistance wire 7 Element lead-out wire 8 Filler 9 Sealing cement 10 Sealing cement 11 Insulation coating material 12 welded portion 13 stainless steel tube 14 resin injection tube

Claims (3)

A platinum resistance thermometer element comprising a cylindrical platinum resistance thermometer element body having a platinum resistance member for temperature measurement inside, and a plurality of element lead wires led out from one end of the element body, In a platinum resistance thermometer that sends a temperature detection signal to the outside through lead wires respectively connected to each element lead wire, the lead wire corresponding to each element lead wire is connected from one end of the element body. The element and insulating resin having the same diameter type platinum resistance thermometer are characterized in that the portion beyond the joint is molded with resin in a cylindrical shape having the same diameter as the outer diameter of the element body. A resistance temperature measuring element comprising a cylindrical element body having a resistance member for temperature measurement inside and a plurality of lead wires provided at one end of the element body has an inner diameter substantially equal to the outer diameter of the element body. Inserted inside an ultrafine metal tube with
Inject the resin into the metal tube on the side with the lead wire while evacuating,
After the resin is cured, the metal tube is immersed in a solvent, and the metal tube is dissolved and removed. A method for producing a platinum resistance temperature detector having the same diameter as an element and an insulating resin. A lead wire is connected to each element lead wire of the platinum resistance thermometer element in which a plurality of element lead wires are derived from one end,
The platinum resistance thermometer element connected to the lead wire is inserted into an ultrafine stainless steel tube having an inner diameter substantially the same as the outer diameter of the element body,
Inject the resin into the stainless steel tube on the side with the lead wire while evacuating,
After curing the resin,
The stainless steel tube is immersed in a solvent, and the stainless steel tube is dissolved and removed.
The lead wire is sealed with a resin having the same outer diameter as that of the platinum resistance element body, and the lead wire portion is integrated with the platinum resistance thermometer element body and an insulating resin. Manufacturing method of the same diameter type platinum resistance thermometer.

Images