JP4042816B2 - Moisture content detection sensor - Google Patents

Description

【００２３】
表１には、同一のおからに対してＪＩＳ試験方法に採用されている加熱乾燥重量測定方式水分計により測定した結果を標準値として併記している。また、表１には、本発明の水分量検知センサー１０で測定した測定値と加熱乾燥重量測定方式水分計で測定した測定値（標準値）との偏差を、標準値からの偏差として表示している。
表１から判るように、本発明の水分量検知センサー１０を用いて得られた水分量の値は、ＪＩＳ試験方法である加熱乾燥重量測定方式水分計を用いて得られた水分量と全範囲にわたって比較的よく一致している。従って、本発明の水分量検知センサー１０は十分に実使用に対応できると考えられる。
【００２４】
以上、本発明の実施の形態を説明したが、本発明は、この実施の形態に限定されるものではなく、例えば、水分量検知センサーによる測定では貯留されている測定対象物に水分量検知センサーの接触部を接触させて測定したが、水分量検知センサーを測定対象物中に埋設あるいは浸漬してもよいし、水分量検知センサーの接触部の上に測定対象物を載せてもよい。更に、搬送中の測定対象物に水分量検知センサーの接触部を接触させたり、水分量検知センサーを測定対象物中に埋設あるいは浸漬してもよいし、水分量検知センサーの接触部の上に測定対象物を通過させてもよい。
また、面状ヒーターの加熱面のサイズを５０ｍｍ×３０ｍｍとしたが、１０ｍｍ×１０ｍｍと小さくすることも可能である。更に、耐熱カバーの裏面部と側壁部はステンレスで構成したが、エポキシ樹脂等の耐熱樹脂により構成することも可能である。耐熱樹脂を使用することにより、測定時の熱損失を更に減少できて測定精度を向上させることができ、水分量検知センサーの軽量化や耐腐食性を向上させることができる。
【００２５】
【発明の効果】
請求項１、２記載の水分量検知センサーにおいては、所定の電力が供給される面状ヒーターと、面状ヒーターの一方面側に接合されている温度測定部と、面状ヒーターの他方面側に設けられている断熱層と、面状ヒーター、温度測定部、及び断熱層を一体化する耐熱カバーとを有するので、面状ヒーターで発生した熱の損失を少なくすると共に測定対象物内での熱移動特性の影響を敏感に温度測定部で検知することができ、短時間で高精度の測定を行なうことができる。また、水分量検知センサーは高価な精密測定機器を使用せず、しかも構造が簡単なため、価格を従来の水分量検知センサーと比較して１／２０程度に抑えることができる。
【００２６】
特に、温度測定部は複数の異なる位置に配置された複数の温度測定素子を有し、複数の温度測定素子から得られる温度の平均値を出力するので、性状が不均質な測定対象物に対しても安定した測定精度を維持することができ、高精度の測定を行なうことができる。
請求項２記載の水分量検知センサーにおいては、断熱層が、面状ヒーターの他方面側に設けられた空気層と、空気層を介して設けられた断熱材とを有しているので、面状ヒーターで発生した熱の損失を最小限に抑えることができ、より高精度の測定を行なうことができる。
【００２７】
【図面の簡単な説明】
【図１】本発明の一実施の形態に係る水分量検知センサーを適用した水分量測定装置の概念図である。
【図２】同水分量検知センサーの温度測定部の概念図である。
【図３】（ａ）、（ｂ）はそれぞれ同水分量検知センサーで測定された測定対象物に対する時間と温度の関係を示す説明図、両対数処理を行なった時間と温度の関係を示す説明図である。
【図４】（ａ）、（ｂ）はそれぞれ同水分量検知センサーで測定された比較用の測定対象物に対する時間と温度の関係を示す説明図、両対数処理を行なった時間と温度の関係を示す説明図である。
【図５】同水分量検知センサーで測定された比較用の測定対象物に対する水分量と温度上昇速度の関係を示す説明図である。
【図６】同水分量検知センサーで測定された比較用のおからに対する時間と温度の関係を示す説明図である。
【図７】同水分量検知センサーで測定された比較用のおからに対する水分量と温度上昇速度の関係を示す説明図である。
【符号の説明】
１０：水分量検知センサー、１１：面上ヒーター、１２：温度測定部、１３：断熱層、１４：耐熱カバー、１５：熱電対、１６：耐熱接着剤層、１７：空気層、１８：断熱材、１９：接触部、２０：裏面部、２１：側壁部、２２：電気ケーブル、２３：信号ケーブル、２４：ケーブル用導管、２５：水分量測定装置、２６：コンピュータ、２７：電源部、２８：測定対象物[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a moisture content detection sensor that measures a moisture content by utilizing heat transfer characteristics in a measurement object.
[0002]
[Prior art]
Conventionally, when measuring the amount of water contained in objects with non-uniform properties such as food, food waste, civil engineering materials, soil, etc., various moisture such as heating type, dielectric type, electric resistance type, electromagnetic wave type, heat conduction type, etc. A volume detection sensor is used.
[0003]
[Problems to be solved by the invention]
However, the heating type moisture content detection sensor measures the moisture content from the weight change before and after drying the object, and can measure a wide range of moisture content from 0 to 100%. There is a problem that it is long. Dielectric moisture sensor is a device that measures the moisture content based on the difference in dielectric constant by applying electricity to the object. The measurement time is short and continuous measurement is possible, but the problem is that the high moisture content region cannot be measured. There is. The electric resistance type moisture detection sensor measures the moisture content based on the difference in electrical resistance by supplying electricity to the object. The measurement time is short and continuous measurement is possible, but the high moisture content region cannot be measured. There is a problem. The electromagnetic wave type moisture amount detection sensor measures the amount of moisture based on the difference in energy absorption amount of the object with respect to infrared irradiation, and has a feature that measurement accuracy is high, measurement time is short, and continuous measurement is possible. However, stability of measurement accuracy can be ensured for objects whose surface condition and color are always constant, for example, paper, flour, etc., but have surface properties that easily scatter electromagnetic waves, for example, garbage, sludge In the case of porous materials such as soil, grains, and fruits, there is a problem that measurement accuracy is not stable. Further, there is a problem that the sensor price is expensive.
[0004]
The heat-conducting water content detection sensor measures the water content by comparing the thermal conductivity of the object with water and the thermal conductivity of the water by external heating, and measures a wide range of moisture content from 0 to 100% in a short time. Can do. However, the detection part of the sensor requires manual precision machining, which hinders mass production. Further, in the measurement, a converter for converting and processing the detection signal of the sensor and an arithmetic processing unit are necessary, and there is a problem that the system becomes expensive when the system is formed as a measuring apparatus. As described above, the conventional moisture amount detection sensor has various problems, and thus has been an obstacle in the application of the moisture amount detection sensor to various fields requiring moisture management.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a moisture amount detection sensor capable of continuously measuring a wide range of moisture amount regions in a short time with high accuracy.
[0005]
[Means for Solving the Problems]
The moisture amount detection sensor according to the present invention that meets the above-described object includes a planar heater to which predetermined power is supplied, a temperature measuring unit joined to one surface of the planar heater, and the planar heater. possess a heat insulating layer provided on the surface side, the planar heater, the temperature measuring unit, and a heat-resistant cover for integrating the heat insulating layer,
The temperature measurement unit includes a plurality of temperature measurement elements that are arranged at different positions and are connected in parallel to output an average temperature, and a heat-resistant resin film is disposed on a side of the temperature measurement unit that contacts the measurement object. and has, wherein the outer heat cover, and an electric cable connected to the outlet the planar heater, a signal cable connected to the temperature measuring unit that has a cable conduit which is disposed inside is provided .
By providing a heat insulation layer on the other side of the planar heater, almost all the heat generated by the planar heater can be conducted from one side of the planar heater to which the temperature measurement unit is joined, approximating heat transfer. Thus, a one-dimensional unsteady heat conduction state can be formed. Accordingly, since the heat generated by the planar heater is conducted through the temperature measuring unit joined to one side of the planar heater, the temperature measuring unit is provided on one side of the planar heater. By adopting a configuration having the temperature measuring element, it is possible to reliably grasp the movement characteristics of the heat generated and conducted from the planar heater as the temperature change. The number of temperature measuring elements is selected according to the area of the heating surface of the planar heater and the properties of the measurement object. For example, when the area of the heating surface of the planar heater is large or the uniformity of the measurement object is low, the number of temperature measurement elements should be increased. On the other hand, when the area of the heating surface of the planar heater is small or the homogeneity of the measurement object is high, the number of temperature measuring elements can be reduced.
[0006]
In the moisture amount detection sensor according to the present invention, the temperature measurement unit includes a plurality of temperature measurement elements arranged at a plurality of different positions, and outputs an average value of temperatures obtained from the plurality of temperature measurement elements. Since a plurality of temperature measuring elements are arranged and an average value of the temperatures measured by each temperature measuring element is output, local influence can be suppressed and stable temperature measurement can always be maintained.
Moreover, in the moisture amount detection sensor according to the present invention, the heat insulating layer includes an air layer provided on the other surface side of the planar heater and a heat insulating material provided via the air layer. A configuration is preferable.
By interposing an air layer between the planar heater and the heat insulating material, the heat insulating property of the heat insulating layer can be improved. For this reason, the heat generated by the planar heater can be reliably conducted to the outside through the temperature measuring unit.
[0007]
[0008]
The measurement principle of the moisture amount detection sensor of the present invention utilizes the thermal diffusivity of the measurement object. The thermal diffusivity of the measurement object is a ratio value indicating the ease of heat transfer with respect to the degree to which the measurement object is warmed or cooled, and is usually represented by thermal conductivity / heat capacity.
Now, when the moisture detection sensor is brought into contact with the measurement object and a predetermined power is supplied to the planar heater to generate heat from the planar heater, the generated heat is conducted into the measurement object via the temperature measurement unit. I will do it. At this time, if the heating time is as short as, for example, about 100 seconds, the movement and evaporation of water in the measurement object can be ignored even if heated rapidly.
Here, if the moisture content of the measurement object is low, the heat transfer in the measurement object is slow, and the heat energy required to warm the water is small, so the heat generated from the surface heater detects the amount of water. A large amount is accumulated on the contact surface between the sensor and the measurement object. For this reason, the rate of temperature increase measured by the temperature measuring unit increases. On the other hand, if the moisture content of the measurement object is high, the heat transferred in the measurement object is fast, and the heat energy required to warm the water is large, so the heat generated from the planar heater is a moisture content detection sensor. Is not accumulated on the contact surface of the measurement object. For this reason, the rate of temperature increase measured by the temperature measuring unit is small. Therefore, when a measurement target is heated under a certain heating condition using a moisture amount detection sensor and the temperature rise rate is obtained from the temperature change at that time, there is a correlation between the moisture amount and the temperature rise rate. It will be.
Therefore, if the moisture content detection sensor obtains the correlation between the moisture content and the rate of temperature rise for an object of the same type as the measurement object and the moisture content is known, this correlation and the actual measurement The water content of the measurement object can be determined by comparing the temperature increase rate obtained using the water content detection sensor with respect to the object.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the accompanying drawings for understanding of the present invention.
Here, FIG. 1 is a conceptual diagram of a moisture measuring device to which a moisture detection sensor according to an embodiment of the present invention is applied, FIG. 2 is a conceptual diagram of a temperature measuring unit of the moisture detection sensor, and FIG. ), (B) are explanatory diagrams showing the relationship between time and temperature with respect to the measurement object measured by the same water content detection sensor, explanatory diagrams showing the relationship between time and temperature after logarithmic processing, and FIG. ), (B) is an explanatory diagram showing the relationship between time and temperature for a comparative measurement object measured by the same water content detection sensor, and an explanatory diagram showing the relationship between time and temperature after logarithmic processing, FIG. 5 is an explanatory diagram showing the relationship between the amount of water and the rate of temperature rise for a comparative measurement object measured by the same water content detection sensor.
[0010]
As shown in FIG. 1, a moisture amount detection sensor 10 according to an embodiment of the present invention includes a planar heater 11 to which predetermined power is supplied, and a temperature bonded to one surface side of the planar heater 11. It has the measurement part 12, the heat insulation layer 13 provided in the other surface side of the planar heater 11, and the heat resistant cover 14 which integrates the planar heater 11, the temperature measurement part 12, and the heat insulation layer 13. As shown in FIG. . Hereinafter, these will be described in detail.
As the planar heater 11, for example, a commercially available planar ceramic heater having a heating capacity of 90 W, a heating surface of 50 mm length × 30 mm width, and a thickness of about 1 mm can be used.
[0011]
As shown in FIGS. 1 and 2, the temperature measurement unit 12 includes, for example, four thermocouples which are examples of temperature measurement elements arranged in parallel at equal intervals over the length direction of the heating surface of the surface heater 11. 15 and a ceramic heat-resistant adhesive layer 16 filled around each thermocouple 15. Since the four thermocouples 15 are connected in parallel, the average value of the temperatures measured by each thermocouple 15 can be output as the measurement result of the temperature measurement unit 12. For this reason, it is possible to always maintain a stable measurement without being strongly affected by local influences.
[0012]
The heat insulating layer 13 includes, for example, an air layer 17 having a thickness of 1 mm and a heat insulating material 18 made of glass fiber having a thickness of 5 mm provided via the air layer 17. By interposing the air layer 17 between the planar heater 11 and the heat insulating material 18, the heat insulating property of the heat insulating layer 13 can be improved. For this reason, the heat generated by the planar heater 11 can be conducted only from the surface where the heat insulating layer 13 is not provided, that is, the surface side where the temperature measuring unit 12 is joined.
[0013]
The heat-resistant cover 14 is provided on the temperature measurement unit 12 side and provided on the heat-insulating layer 13 side, which is an example of a heat-resistant resin having a thickness of about 0.1 mm, which is an example of a heat-resistant resin. A stainless steel back surface portion 20 and a stainless steel side wall portion 21 connecting the contact portion 19 and the back surface portion 20. Further, the side wall portion 21 is provided with a hole (not shown) through which a pair of electric cables 22 for the planar heater 11 and a set of signal cables 23 for the temperature measuring unit 12 pass, and is led out of the heat resistant cover 14. The electric cable 22 and the signal cable 23 thus assembled are assembled in a cable conduit 24 provided on the back surface portion 20.
[0014]
Next, a water content measuring device 25 to which the water content detection sensor 10 according to one embodiment of the present invention is applied will be described.
As shown in FIG. 1, the water content measurement device 25 includes a water content detection sensor 10, a computer 26 that processes an output signal from the temperature measurement unit 12 in the water content detection sensor 10, the water content detection sensor 10, and the computer. 26, for example, a power supply unit 27 having a constant voltage source. The computer 26 is composed of, for example, a personal computer, and displays an A / D conversion unit that performs A / D conversion on the input signal, a calculation unit that processes the A / D converted signal, and a processing result of the calculation unit. And a display unit.
[0015]
Then, the moisture content measuring method which concerns on one embodiment of this invention using the moisture content measuring apparatus 25 is demonstrated in detail.
The moisture content measuring method of the present embodiment includes a first step of heating the planar heater 11 by bringing the moisture amount detection sensor 10 into contact with the measurement object 28 and supplying a predetermined power to the planar heater 11. The second step for obtaining an actual measured value of the temperature rise rate from the temperature detected by the temperature measuring unit 12 when the heater 11 is heated, and the measured value of the temperature rise rate obtained in the second step and the measurement object 28 are the same. By comparing the temperature increase rate obtained by separately measuring an object whose moisture content is known (comparative measurement object) and the correlation between the moisture content, And a third step for determining the amount of moisture. Hereinafter, each process will be described in detail.
[0016]
(1) First Step As shown in FIG. 1, electric power is supplied from the power supply unit 27 to the moisture amount detection sensor 10 and the computer 26, and the measurement object 28 in which the contact portion 19 of the moisture amount detection sensor 10 is stored is stored. Touch the top. Thereafter, a measurement start switch (not shown) of the moisture amount detection sensor 10 is turned on, and 90 W of power is supplied to the planar heater 11 for 100 seconds, for example. Since the heating time of the planar heater 11 is as short as 100 seconds, the movement and evaporation of water in the measurement object 28 can be ignored.
[0017]
(2) When supplying 90 W of electric power to the second process planar heater 11 for 100 seconds, the temperature measurement unit 12 measures the temperature. The measurement value obtained by the temperature measurement unit 12 is input to the computer 26 and processed to obtain the relationship between time and temperature. FIG. 3A shows the relationship between time and temperature shown on the display unit.
In the planar heater 11, since the thickness of the planar heater 11 is as thin as 1 mm with respect to the size of the heating surface (50 mm × 30 mm), heat conducted from the end of the planar heater 11 can be ignored. Further, since the temperature measuring unit 12 is joined to one surface side of the planar heater 11 and the heat insulating material 18 is provided on the other surface side through the air layer 17, to the other surface side of the planar heater 11. The heat transfer is prevented, and almost all the heat generated in the planar heater 11 is conducted to the outside of the planar heater 11 through the temperature measuring unit 12. For this reason, if the processing unit of the computer 26 is provided with processing means for performing a logarithmic operation on the relationship between time and temperature shown in FIG. The linear relationship is as shown in FIG. Therefore, the slope of this straight line corresponds to the temperature rise rate.
[0018]
(3) For the same type of object as the third process measurement object 28, for example, a measurement object for comparison is prepared in which the moisture content is adjusted to 20%, 40%, 60%, and 80%. To do. When the contact portion 19 of the moisture amount detection sensor 10 is brought into contact with the measurement object for comparison and the electric power of 90 W is supplied to the planar heater 11 for 100 seconds, the temperature is measured by the temperature measurement portion 12. . The relationship between the obtained time and temperature is shown in FIG. Since a one-dimensional unsteady heat conduction state can be assumed for the measurement object for comparison, when logarithmic calculation is performed on the relationship between time and temperature shown in FIG. 4 (a), FIG. 4 (b). A linear relationship as shown in FIG. Accordingly, the inclinations of straight lines a ₁ , a ₂ , a ₃ , and a ₄ shown in FIG. 4 (b) are 20%, 40%, 60%, and 80% of the measurement objects for comparison. Corresponds to the temperature rise rate. Therefore, when the moisture content is plotted on the horizontal axis and the temperature rise rate at that time is plotted on the vertical axis, the relationship between the moisture content and the temperature rise rate shown in FIG. 5 is obtained.
[0019]
When an interpolation curve for interpolating each point shown in FIG. 5 is obtained, an arbitrary amount of moisture in a range of 20 to 80% is obtained with respect to an object of the same type as the measurement object 28, that is, a measurement object for comparison. The value of the temperature rise rate with respect to the amount of moisture can be estimated. Accordingly, if the function of the interpolation curve shown in FIG. 5 is input to the calculation unit of the computer 26, the measured value of the temperature rise rate obtained for the measurement object 28 is substituted into the function of the interpolation curve. By doing so, the moisture content of the measuring object 28 can be determined.
[0020]
【Example】
The moisture content after applying the moisture content measurement method was measured using the moisture content measuring device 25 using the moisture content detection sensor 10.
(1) Derivation of quantitative relationship between moisture content and temperature rise rate for comparison okara First, in order to obtain the relationship between the moisture content from okara and the temperature rise rate, the moisture content from okara is 20% and 40%. Adjustments were made to be 60% and 80%. Subsequently, the contact portion 19 of the moisture amount detection sensor 10 is brought into contact with the moisture-adjusted okara, 90 W of electric power is supplied to the planar heater 11 and heated for 100 seconds, and the temperature measurement unit 12 sets the temperature at that time. It was measured. The output of the temperature measurement unit 12 was input to the computer 26, and the temperature increase rate was obtained by a processing means for performing a logarithmic calculation provided in the calculation unit. FIG. 6 shows the relationship between time and temperature measured by the temperature measuring unit 12. For the relationship shown in FIG. 6, the temperature rise rate is obtained by the processing means for performing the logarithmic computation provided in the computation unit of the computer 26, and further, a function of an interpolation curve indicating the relationship between the moisture amount and the temperature rise rate is obtained. . FIG. 7 shows the relationship between the obtained moisture content and the temperature rise rate and the interpolation curve.
[0021]
(2) Okara moisture content measurement The contact portion 19 of the moisture amount detection sensor 10 is brought into contact with the okara of the measurement object having various moisture amounts, and 90 W of electric power is supplied to the planar heater 11 to 100 Then, the temperature was measured by the temperature measuring unit 12. The output of the temperature measurement unit 12 was input to the computer 26, and the temperature increase rate was obtained by a processing means for performing a logarithmic calculation provided in the calculation unit. The obtained temperature increase rate was substituted into the function of the interpolation curve shown in FIG. The results are shown in Table 1.
[0022]
[Table 1]

[0023]
In Table 1, the result measured by the heat dry weight measuring method moisture meter employed in the JIS test method for the same okara is shown as a standard value. In Table 1, the deviation between the measured value measured by the moisture amount detection sensor 10 of the present invention and the measured value (standard value) measured by the heat-dry weight measuring method moisture meter is displayed as a deviation from the standard value. ing.
As can be seen from Table 1, the water content value obtained using the water content detection sensor 10 of the present invention is the total amount and the water content obtained using the heat dry weight measuring method moisture meter which is a JIS test method. A relatively good match across. Therefore, it is considered that the moisture amount detection sensor 10 of the present invention can sufficiently cope with actual use.
[0024]
As mentioned above, although embodiment of this invention was described, this invention is not limited to this embodiment, For example, in the measurement by a moisture content detection sensor, the moisture content detection sensor is stored in the measurement object stored However, the moisture content detection sensor may be embedded or immersed in the measurement object, or the measurement object may be placed on the contact portion of the moisture content detection sensor. Furthermore, the contact portion of the moisture amount detection sensor may be brought into contact with the measurement object being transported, or the moisture amount detection sensor may be embedded or immersed in the measurement object, or on the contact portion of the moisture amount detection sensor. The measurement object may be passed.
Moreover, although the size of the heating surface of the planar heater is 50 mm × 30 mm, it can be reduced to 10 mm × 10 mm. Furthermore, although the back surface part and the side wall part of the heat-resistant cover are made of stainless steel, they can be made of heat-resistant resin such as epoxy resin. By using a heat resistant resin, the heat loss during measurement can be further reduced, the measurement accuracy can be improved, and the weight and corrosion resistance of the moisture amount detection sensor can be improved.
[0025]
【The invention's effect】
The moisture amount detection sensor according to claim 1 or 2, wherein a planar heater to which predetermined power is supplied, a temperature measuring unit joined to one side of the planar heater, and the other side of the planar heater And a heat-resistant cover that integrates the surface heater, the temperature measuring unit, and the heat-insulating layer, so that heat loss generated by the surface heater can be reduced and The influence of the heat transfer characteristic can be sensitively detected by the temperature measurement unit, and high-precision measurement can be performed in a short time. Further, since the moisture amount detection sensor does not use an expensive precision measuring instrument and has a simple structure, the price can be reduced to about 1/20 compared with a conventional moisture amount detection sensor.
[0026]
In particular, the temperature measuring unit has a plurality of temperature measuring elements arranged at a plurality of different positions, and outputs an average value of the temperatures obtained from the plurality of temperature measuring elements, so that it is suitable for a measurement object with non-homogeneous properties. However, stable measurement accuracy can be maintained, and high-accuracy measurement can be performed.
In the moisture amount detection sensor according to claim 2 , the heat insulating layer includes an air layer provided on the other surface side of the planar heater and a heat insulating material provided via the air layer. Loss of heat generated by the heater can be minimized, and more accurate measurement can be performed.
[0027]
[Brief description of the drawings]
FIG. 1 is a conceptual diagram of a moisture content measuring apparatus to which a moisture content detection sensor according to an embodiment of the present invention is applied.
FIG. 2 is a conceptual diagram of a temperature measurement unit of the moisture amount detection sensor.
FIGS. 3A and 3B are explanatory diagrams showing the relationship between time and temperature for a measurement object measured by the same moisture amount detection sensor, and the relationship between time and temperature after logarithmic processing. FIGS. FIG.
FIGS. 4A and 4B are explanatory diagrams showing the relationship between time and temperature for a comparative measurement object measured by the same water content detection sensor, and the relationship between time and temperature after logarithmic processing. It is explanatory drawing which shows.
FIG. 5 is an explanatory diagram showing the relationship between the amount of water and the rate of temperature rise for a comparative measurement object measured by the same water content detection sensor.
FIG. 6 is an explanatory diagram showing a relationship between time and temperature for a comparative okara measured by the moisture amount detection sensor.
FIG. 7 is an explanatory diagram showing the relationship between the amount of moisture and the temperature rise rate for the comparative okara measured by the same moisture amount detection sensor.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10: Moisture content detection sensor, 11: Surface heater, 12: Temperature measurement part, 13: Heat insulation layer, 14: Heat-resistant cover, 15: Thermocouple, 16: Heat-resistant adhesive layer, 17: Air layer, 18: Heat insulation material , 19: contact portion, 20: back surface portion, 21: side wall portion, 22: electric cable, 23: signal cable, 24: cable conduit, 25: moisture measuring device, 26: computer, 27: power supply portion, 28: Measurement object

Claims (2)

A planar heater to which a predetermined power is supplied, a temperature measuring unit joined to one side of the planar heater, a heat insulating layer provided on the other side of the planar heater, and the planar heater, the temperature measuring unit, and possess a heat cover for integrating the heat insulating layer,
The temperature measurement unit includes a plurality of temperature measurement elements that are arranged in different positions and connected in parallel to output an average temperature, and a heat-resistant resin film is disposed on a side of the temperature measurement unit that contacts the measurement object. and has, wherein the outer heat cover, and an electric cable connected to the outlet the planar heater, a signal cable connected to the temperature measuring unit that has a cable conduit which is disposed inside is provided Moisture content detection sensor.   The moisture amount detection sensor according to claim 1, wherein the heat insulating layer includes an air layer provided on the other surface side of the planar heater and a heat insulating material provided via the air layer. Moisture content detection sensor.

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