JPH0577738U - Thermistor temperature sensor - Google Patents

Abstract

(57) [Abstract] [Purpose] A thermistor temperature sensor that improves drainage properties when water droplets adhere to reduce the wet-bulb effect and is almost unaffected by radiant heat from sunlight. An object is to provide a temperature sensor. In a thermistor temperature sensor having a structure in which a radial type thermistor element 1 having a plurality of lead wires 2 in one direction is sealed by a sealing glass 3, a plurality of lead wires 2 are covered with lead wire protection tubes 4. .. Then, a resin coating 5 made of a resin having water repellency is applied to the entire surfaces of the sealing glass 3 and the lead wire protection tube 4, and then an external protection tube 6 for covering the sealing glass 3 and the lead wire protection tube 4 is provided. Compose by. Further, in this case, the outer surface of the outer protection tube 6 is further coated with a metal coating 7.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a thermistor temperature sensor, and particularly to a thermistor used in a thick fog or cloud, or in the rain, such as a temperature sensor used in a radiosonde for weather observation. The present invention relates to a temperature sensor.

[0002] A temperature sensor used for a radiosonde for meteorological observation does not show a temperature higher than the actual temperature due to the influence of radiation even when used in a state where it is exposed to direct sunlight, and a thick fog or When used in the cloud or in the rain, it is required that it does not show a temperature lower than the actual temperature due to water wetting.

[0003]

[Prior Art]

 FIG. 3 shows a conventional temperature measuring thermistor temperature sensor, which is conventionally used in a weather observing radiosonde or the like, and is composed of an axial type thermistor as shown in the drawing. Reference numeral 21 is a thermistor element formed in a cylindrical shape or the like, and lead wires 22 and 23 are axially connected from both ends thereof. The thermistor element 21 has a structure in which it is integrally sealed by a sealing glass 24, and a white paint film 25 is applied to the entire surface of the sealing glass 24 and the lead wires 22 and 23. It has a structure.

As described above, in the conventional thermistor temperature sensor for a radiosonde, the thermistor element and the lead wire are covered with the paint film to improve drainage when wet with water. This is because when water adheres to the surface, the same effect as a wet-bulb in a wet-wet-bulb hygrometer (wet-bulb effect) is generated based on the evaporation of this moisture, and the temperature is lower than the actual temperature. This is to prevent the occurrence of the phenomenon.

Further, in this case, the paint film 25 is formed of white paint so as to prevent the thermistor temperature sensor from showing a temperature higher than the actual temperature when it receives radiant heat such as sunlight. ing.

[0006]

[Problems to be solved by the device]

 Since the radiosonde rises at a speed of about 5 m per second, it is necessary to use a thermistor element that is as small and quick as possible in order to accurately measure changes in weather conditions that change from moment to moment. However, in addition to that, if you enter a thick fog or cloud during climbing, or if you encounter rainfall, make the drainage as good as possible so that water droplets do not adhere to the surface As a result, it is possible to suppress the temperature measurement error due to the wet bulb effect caused by the evaporation of the attached water, and improve the measurement accuracy.

When the radiosonde enters the mist or cloud while rising, the temperature of the minute water particles in the atmosphere is not different from the atmospheric temperature, so these water particles form water droplets on the surface of the thermistor temperature sensor. Even if it adheres, it is unlikely that a difference between the temperature and the indicated temperature will occur. This is because it is considered that the water vapor is saturated in such a place, the water droplets adhering to the thermistor temperature sensor evaporate, and the heat of vaporization is taken away, so that the reading of the thermistor temperature sensor does not decrease. is there. However, when the radiosonde rises further above the clouds, water vaporization continues as long as water droplets are attached to the thermistor temperature sensor, which removes the latent heat of vaporization and the indicated temperature is the ambient temperature. Will be lower than. By analogy with a dry-wet bulb hygrometer, we call it the wet-bulb effect.By miniaturizing the thermistor temperature sensor in order to speed up the response of the thermistor temperature sensor, the thermistor temperature sensor has traditionally existed. The wet-bulb effect tends to be even greater.

FIG. 4 shows an example of a wet-bulb effect in a radiosonde using a conventional thermistor temperature sensor, and shows a case where there is a cloud in the sky and the radiosonde passes through the cloud and rises. It is shown that due to the wet-bulb effect, the indicated temperature in a certain range had a maximum decrease of about 4 ° C from the value estimated from the height of the radiosonde.

Therefore, as a means for reducing the wet-bulb effect, it is effective to reduce water droplets attached to the thermistor temperature sensor as much as possible. For that purpose, it is necessary to make the thermistor temperature sensor have a structure that causes water to run off as soon as possible even if water droplets adhere to it.

In the conventional thermistor temperature sensor for a radiosonde shown in FIG. 3, the coating film 25 is applied to improve the drainage when water drops adhere to the temperature sensor. In case of entering or encountering rainfall, some water drops are unavoidable. Therefore, when it passes through such a place and becomes clear, the above-mentioned wet-bulb effect occurs, causing a large error in the measured temperature. Therefore, there has been a problem in that the value measured by the thermistor temperature sensor must be corrected to a considerable degree.

Further, in the conventional thermistor temperature sensor, by further forming the above-mentioned paint film 25 with white paint, sunlight is reflected and the temperature rise due to absorption of radiant heat is suppressed as small as possible. Although it has been taken into consideration, there was a problem in that the effect of radiation could not be completely eliminated, and some measurement errors would inevitably be accompanied.

The present invention is intended to solve such a problem of the prior art, and in a thermistor temperature sensor for a radio ozone detector or the like, improves the drainage property when water droplets adhere to improve the wet bulb effect. The object is to provide a thermistor temperature sensor that is small in size and is hardly affected by radiation such as sunlight.

[0013]

[Means for Solving the Problems]

 The thermistor temperature sensor of the present invention is a thermistor temperature sensor having a structure in which a radial type thermistor element having a plurality of lead wires in one direction is sealed with sealing glass, and each lead wire is covered with a lead wire protection tube. The outer surface of the sealing glass and the lead wire protection tube is covered with a resin coating made of a resin having water repellency, and then an external protection tube covering the sealing glass and the lead wire protection tube is provided. .. Further, the thermistor temperature sensor of the present invention is characterized in that, in the above-mentioned structure, a metal coating is applied to the outer surface of the outer protective tube.

[0014]

[Action]

 The thermistor temperature sensor of the present invention has a structure in which a radial type thermistor element 1 having a plurality of lead wires 2 in one direction is sealed by a sealing glass 3 as shown in FIG. The thermistor temperature sensor is protected by covering each lead wire 2 with a lead wire protection tube 4. Then, the resin coating film 5 made of a resin having water repellency is applied to the entire surfaces of the sealing glass 3 and the lead wire protection tubes 4 so that water droplets are hard to be attached. Further, the sealing glass 3 and each lead wire protection tube 4 are covered with an external protection tube 6 to improve protection and drainage.

As described above, in the thermistor temperature sensor of the present invention, since the resin coating 5 is applied to the entire surface of the sealing glass 3 and each lead wire protection tube 4 so as to have water repellency, water droplets are not generated on the outer surface. Less adherence. Furthermore, since the external protection tube 6 is provided, the adhesion of water drops is reduced. Along with this, the attachment method may be made vertical with the lead wire portion facing downward so that water droplets adhering to the surfaces of the lead wire protection tube 4 and the external protection tube 6 can easily drop. it can. Therefore, when the thermistor temperature sensor of the present invention is used for temperature measurement in a radiosonde for meteorological observation, etc., water droplets will be dropped even if the radiosonde rises into clouds or fog or encounters rainfall. Is less likely to adhere, and thus when the temperature rises further into the clear region, the above-mentioned wet bulb effect based on the evaporation of water droplets is prevented from causing a decrease in the indicated temperature.

The thermistor temperature sensor of the present invention, as shown in FIG. 1 as an embodiment thereof, has a structure in which, in addition to the above-mentioned structure, a metal coating 7 is applied to the outer surface of the outer protective tube to reflect heat radiation. I have to. Therefore, when the thermistor temperature sensor of the present invention is used for measuring the temperature in a radiosonde for weather observation or the like, it is possible to prevent the indicated temperature from rising due to the irradiation of sunlight.

[0017]

【Example】

 FIG. 1 shows an embodiment of the present invention, which is constructed by using a radial type thermistor element as shown. Reference numeral 1 is a thermistor element, and a plurality of lead wires 2 are connected in one direction from both upper and lower ends thereof. The thermistor element 1 has a structure in which it is integrally sealed with, for example, an ellipsoidal sealing glass 3. The lead wire 2 is covered with a lead wire protection tube 4. It is preferable to use, for example, a flexible polyimide tube as the lead wire protection tube 4.

The entire surface of the sealing glass 3 of the thermistor temperature sensor and the lead wire protection tube 4 is coated with a resin coating 5 made of a resin having water repellency. This resin film 5 may be formed by dipping using a suitable fluororesin coating material such as V Freon under the trade name, or a similar water repellent fluororesin containing tetrafluoroethylene (TFE) may be used. It may be formed by a spray process.

The coated thermistor temperature sensor is provided with an external protective tube 6 that covers the entire surfaces of the sealing glass 3 and the lead wire protective tube 4. The outer protective tube 6 is, for example, a flexible polyimide tube having a blind end on one side, and the blind end is covered on the sealing glass 3, and then the above-mentioned fluororesin paint, for example, V Freon under the trade name is used. To be brought into close contact with the outer surface of the sealing glass 3. In FIG. 1, reference numeral 8 indicates such a bonded portion. The other end of the outer protective tube 6 may be open or sealed.

Next, a metal coating 7 is provided on the entire outer surface of the outer protective tube 6. The material of the metal coating 7 is aluminum (Al), silver (Ag), gold (Au), copper (Cu), rhodium (Rh), etc., and the wavelength range in which the light reflectance is the highest depending on the purpose. It can be selected and used, and these metals are deposited by a method such as vapor deposition or sputtering to form a film. Depending on the type of metal, it is possible to use a plating method.

FIG. 2 shows the spectral reflectance of a metal surface, and shows the case where light of various wavelengths (μm) is vertically projected onto a fresh surface prepared by vacuum deposition of various metals. The reflectance (%) is shown. Good reflective surfaces are obtained by rapid vapor deposition in a high vacuum, whose reflectivity is usually higher than that of surfaces prepared by sputtering the same metal. Fig. 2 is based on the chronological table of science (1989 edition) edited by the National Astronomical Observatory of Japan. As is clear from FIG. 2, it is possible to select those metals that have the highest reflectance depending on the wavelength range used, but aluminum is particularly high for light of each wavelength. Since it has reflectivity, it is most suitable when it is necessary to effectively reflect the sunlight and remove the effect of radiant heat on the thermistor temperature sensor, such as a weathering radiosonde.

In this way, a resin coating 9 similar to the resin coating 5 of the lead wire protection tube 4 is formed on the inner and outer surfaces of the outer protective tube 6 having the outer surface coated with the metal coating 7. The resin coating 9 can be formed by using the same material as the resin coating 5 and by the same process, but is made of a transparent resin so as not to impair the reflection ability of the metal coating 7. It is desirable to form a thin film.

As described above, since the thermistor temperature sensor of the present invention uses the radial type thermistor element, the direction of the lead wire is only one direction. Therefore, the mounting direction should be devised so that the lead wire is at the bottom. Can improve drainability. Further, a lead tube 2 of the thermistor element is covered with a protective tube 4, a resin coating 5 having water repellency is applied to the surfaces of the sealing glass 3 and the lead wire protecting tube 4, and the sealing glass 3 and the lead wire protecting tube 4 are included. Since the whole body is covered with the external protection tube 6, the surface is well drained. Therefore, a weather-observing radiosonde equipped with such a thermistor temperature sensor may enter into the fog or cloud while rising, or it may rain. If there is, the amount of water remaining attached to the surface of the thermistor temperature sensor is much smaller than that of the conventional structure. As a result, the time when the wet-bulb effect appears is significantly shortened, and the outside air temperature can be measured more accurately.

Furthermore, since the thermistor temperature sensor of the present invention has the metal coating 7 such as aluminum on the outer surface of the external protection tube 6, the effect of heat radiation on the thermistor temperature sensor can be effectively removed. Therefore, in the case of a radiosonde for meteorological observation, it is possible to prevent the indicated temperature from rising due to the effect of sunlight during the rising. In the case of the radiosonde for weather observation using the thermistor temperature sensor of the present invention, the indicated temperature was lower than that of the one using the conventional thermistor temperature sensor. From this, it is clear that in the case of the thermistor temperature sensor of the present invention, the influence of sunlight is small and the temperature measurement in such a case can be performed with higher accuracy.

In addition, in the thermistor temperature sensor of the present invention, as described above, the resin film 9 having water repellency is further provided on the inner and outer surfaces of the outer protective tube 6 having the metal film 7 on the outer surface to improve the drainage property. You may make it improve more. As the resin in this case, the same material as the resin coating 5 is used, and the resin can be applied by the same method.

Further, in the thermistor temperature sensor of the present invention, a metal coating 10 similar to the metal coating 8 is provided on the entire surface of the sealing glass 3 and the lead wire protecting tube 4 so that the heat radiation is reflected also on this surface. You can In this case, the penetrating portion of the lead wire 2 in the sealing glass 3 and the end portion of the lead wire protecting tube 4 are previously water-tightly adhered to each other using an appropriate fluororesin paint or the like similar to the above-mentioned adhering portion 8. , It is necessary to prevent a short circuit between leads due to the deposited metal. In FIG. 1, reference numeral 11 indicates such a bonded portion.

In order to fix the external protection tube 6 to the sealing glass 3, regardless of the bonding method, the external protection tube 6 is made of a heat-shrinkable material and heat-shrinked and fixed. You may do so.

[0028]

[Effect of the device]

 As described above, according to the present invention, since the radial type thermistor element is used, the drainage property can be improved by considering the mounting direction, and the water-repellent coating is applied to further improve the drainage property. Can be good. Therefore, when used in a radiosonde for meteorological observation, when entering fog or cloud, or when encountering rainfall, there is little decrease in measured temperature due to evaporation of adhering water, and there is no decrease in temperature. The time it takes is shorter. Further, according to the present invention, since a metal coating such as aluminum that reflects thermal radiation is provided, it is possible to reduce an increase in measurement temperature due to the influence of sunlight when used in a weather observation radiosonde or the like. .. Therefore, according to the thermistor temperature sensor of the present invention, particularly when used for a weather observation radiosonde or the like, it is possible to remove an error factor of the temperature measurement due to the influence of the external environment encountered during the ascent and perform an accurate measurement. become able to.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of the present invention.

FIG. 2 is a diagram showing a spectral reflectance of a metal surface.

FIG. 3 is a diagram showing a conventional temperature measuring thermistor temperature sensor.

FIG. 4 is a diagram showing an example of a wet bulb effect.

[Explanation of symbols]

 1 Thermistor element 2 Lead wire 3 Sealing glass 4 Lead wire protection tube 5 Resin coating 6 External protection tube 7 Metal coating

Claims (3)

[Scope of utility model registration request] 1. A thermistor temperature sensor having a structure in which a radial type thermistor element (1) having a plurality of lead wires (2) in one direction is sealed by a sealing glass (3). ) Is covered with a lead wire protection tube (4), and a resin coating (5) made of a water-repellent resin is applied to the entire surfaces of the sealing glass (3) and the lead wire protection tube (4), and then the sealing A thermistor temperature sensor, characterized in that an external protective tube (6) is provided to cover the protective glass (3) and the lead wire protective tube (4). 2. A thermistor temperature sensor having a structure in which a radial type thermistor element (1) having a plurality of lead wires (2) in one direction is sealed by a sealing glass (3). ) Is covered with a lead wire protection tube (4), and a resin coating (5) made of a water-repellent resin is applied to the entire surfaces of the sealing glass (3) and the lead wire protection tube (4), and then the sealing An external protective tube (6) is provided to cover the protective glass (3) and the lead wire protective tube (4), and a metal coating (7) is applied to the outer surface of the external protective tube (6). Thermistor temperature sensor. 3. The metal coating (7) is made of aluminum (A
The thermistor temperature sensor according to claim 2, which is formed by vapor deposition or sputtering of l).