JP2009063411A - Temperature detection apparatus and temperature detection method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a temperature detection apparatus for surely and easily identifying a region in which a temperature meets a temperature condition without an increase in a manufacturing cost. <P>SOLUTION: The temperature detection apparatus 1 comprises: a two-dimensional temperature sensor 2 for outputting a sensor signal S1 for indicating the temperature detected by each detection element among a plurality of the arrayed detection elements; a data generation section (a control section 8) for generating image data of a temperature distribution image based on the sensor signal S1; and a storage section 3 for storing the image data. When the sensor signal S1 for indicating the temperature meeting the predetermined temperature condition is outputted, the control section 8 implements a storage control process for storing the image data generated based on the sensor signal S1 in the storage section 3. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a temperature detection device and a temperature detection method for generating image data of a temperature distribution image based on a sensor signal from a two-dimensional temperature sensor.

  As this type of temperature detecting device, an infrared radiation temperature measuring device (hereinafter also referred to as “measuring device”) configured to display a thermal image (temperature distribution image) is disclosed in Japanese Utility Model Laid-Open No. 5-27636. . In this measuring apparatus, the temperature signal output from the infrared detector is amplified by an amplifier, corrected by a signal processing circuit, and output as temperature data to a high-speed arithmetic control unit and a memory. In response to this, the high-speed calculation control unit calculates the maximum value, the minimum value, and the average value of the output temperature data, and outputs the calculation result and thermal image data based on the temperature data to the display device. As a result, a thermal image corresponding to the temperature of the subject and the above maximum value, minimum value, average value, and the like are displayed on the display device in real time.

In this case, in this measuring apparatus, when the calculated maximum value, minimum value, average value, etc. exceed a predetermined standard, the high-speed calculation control unit performs lighting of LEDs, etc., output of notification sound by a buzzer, etc. Execute this to notify that effect (output an alarm). Further, in this measuring apparatus, instead of the real-time display described above, the high-speed calculation control unit calculates the maximum value, the minimum value, and the average value of the temperature data stored in the memory, and calculates the calculation result and the temperature data. The thermal image data based on the image data is output to the display device, and the thermal image, the maximum value, the minimum value, the average value, and the like can be displayed on the display device at an arbitrary timing.
JP-A-5-27636 (Pages 5-7, FIGS. 1 and 2)

  However, the conventional measuring apparatus has the following problems. In other words, the conventional measuring apparatus adopts a configuration in which an alarm is output by the high-speed arithmetic control unit when the maximum value, minimum value, average value, etc. of the temperature data sequentially output from the signal processing circuit exceed the reference temperature. ing. In this case, in this type of measurement device (temperature detection device), when a target object (subject) for detecting temperature is large, or when a plurality of target objects are separated from each other and scattered in a wide area, For example, by holding the device in the hand and moving the device to change the direction in which the temperature sensor (infrared detector in a conventional measuring device) is directed, the end of the object is moved to the other end (or the object is A usage pattern in which observation is performed sequentially (from the end of the scattered area to the other end) may be employed. In such a usage pattern (a usage pattern in which the orientation of the sensor unit is sequentially changed while displaying a thermal image in real time), in the conventional measurement apparatus, an abnormal heat generation site is detected, and a calculation result ( When any one of the maximum value, the minimum value, and the average value) exceeds the reference temperature, an alarm is output as described above.

  However, in the conventional measuring apparatus, when the orientation of the sensor unit (infrared detector) is changed while performing real-time display of a thermal image or the like based on temperature data sequentially output from the signal processing circuit, The apparatus employs a configuration in which a thermal image of a part facing the sensor unit at that time is displayed. Therefore, when the abnormal heat generation part is detected and the alarm is output by the high-speed calculation control part while changing the direction in which the sensor part is directed, the sensor part is directed in a direction different from the abnormal heat generation part. There is a case where the abnormal heat generation part that causes the alarm output does not exist in the thermal image of the display device. For this reason, the conventional measuring apparatus adopts a configuration in which an alarm is output when a temperature exceeding the reference temperature is detected in a usage mode in which a thermal image is displayed in real time while sequentially changing the direction of the sensor unit. Nevertheless, there is a problem that it is difficult to specify which part of the temperature exceeds the reference temperature.

  In this case, as described above, the conventional measuring apparatus employs a configuration in which the temperature data output from the signal processing circuit is sequentially stored in the memory. For this reason, when an alarm is output during the real-time display of the thermal image while sequentially changing the orientation of the sensor unit as in the above example, the temperature data stored in the memory is read to An image, a maximum value, a minimum value, an average value, and the like are displayed on the display device, and a part exceeding the reference temperature can be specified. However, in the conventional measuring apparatus, since a large amount of temperature data including the temperature data for the portion below the reference temperature is stored in the memory, the temperature data at the time when the alarm is output is found and the desired thermal image is obtained. It is very complicated to display the image on the display device. In addition, in order to store a large amount of temperature data in this way, it is necessary to mount a large-capacity memory, so that there is a problem that the manufacturing cost of the conventional measuring apparatus is increased. is there.

  The present invention has been made in view of such problems, and a temperature detection apparatus and a temperature detection method that can reliably and easily specify a portion that is at a temperature condition without causing an increase in manufacturing cost. The main purpose is to provide

  In order to achieve the above object, the temperature detection apparatus according to claim 1 is based on a two-dimensional temperature sensor in which a plurality of detection elements are arranged and outputs a sensor signal indicating a temperature detected by each detection element, and the sensor signal. And a data generation unit that generates image data of a temperature distribution image, the storage unit storing the image data, and the sensor signal indicating the temperature satisfying a preset temperature condition. And a control unit that executes a storage control process for storing the image data generated based on the sensor signal in the storage unit when output. In this case, the “temperature satisfying a preset temperature condition” in the present invention includes “a temperature equal to or higher than a preset temperature”, “a temperature exceeding a preset temperature”, “a preset temperature”. "Temperature below temperature", "Temperature lower than preset temperature", "Temperature within preset temperature range", and "Temperature outside preset temperature range" are included.

  The temperature detection device according to claim 2 is the temperature detection device according to claim 1, wherein the control unit includes a control region in a determination region defined in a central portion of the temperature detection region where the detection elements are arranged. The storage control process is executed only when the sensor signal indicating the temperature satisfying the temperature condition is output from the detection element.

  Furthermore, the temperature detection device according to claim 3 is the temperature detection device according to claim 1 or 2, further comprising a display unit for displaying the temperature distribution image, wherein the control unit has a preset warning display start condition. When satisfied, the temperature distribution image based on the image data stored in the storage unit is displayed on the display unit.

  The temperature detection device according to claim 4 is the temperature detection device according to any one of claims 1 to 3, wherein the data generation unit corresponds to a position of the detection element that detects a temperature that satisfies the temperature condition. The image data is generated by emphasizing the pixels to be processed.

  Furthermore, the temperature detection device according to claim 5 is the temperature detection device according to claim 4, wherein the data generation unit is arranged around the pixel corresponding to the position of the detection element that detects the temperature satisfying the temperature condition. The image data is generated by emphasizing a predetermined number of pixels.

  The temperature detection method according to claim 6 is a temperature distribution image based on a sensor signal from a two-dimensional temperature sensor that outputs a sensor signal indicating a temperature detected by each of the plurality of detection elements. A temperature detection method for generating the image data and storing the image data generated based on the sensor signal in a storage unit when the sensor signal indicating the temperature satisfying a preset temperature condition is output.

  According to the temperature detection device according to claim 1 and the temperature detection method according to claim 6, a sensor from a two-dimensional temperature sensor that outputs a sensor signal indicating a temperature detected by each of the detection elements arranged in a plurality of detection elements. Image data of the temperature distribution image is generated based on the signal, and when the sensor signal indicating the temperature satisfying the preset temperature condition is output, the image data generated based on the sensor signal is stored in the storage unit By executing the storage control process, even if one portion misses the temperature distribution image that satisfies the temperature condition, the missed temperature distribution image is based on the image data stored in the storage unit. Can be displayed on the display unit, and the part having the temperature satisfying the temperature condition can be reliably and easily specified. Further, according to the temperature detection device and the temperature detection method, the storage control process for storing the image data in the storage unit only when the temperature detected by any of the detection elements reaches a temperature condition is performed. Compared with the conventional measuring device configured to store all the temperature data output from the signal processing circuit in the memory, the amount of image data to be stored in the storage unit is small, so that the memory capacity is small. As a result, it is possible to sufficiently reduce the manufacturing cost of the temperature detecting device. In addition, since it is not necessary to search temperature data for a part that satisfies the temperature condition from a large amount of temperature data, a desired temperature distribution image can be easily displayed on the display unit in a short time, Or output to the device.

  According to the temperature detection device of the second aspect, the sensor signal indicating the temperature condition is output from the detection element in the determination region defined in the center of the temperature detection region where the detection elements are arranged. In the usage mode in which the temperature detection device is moved so as to change the direction of the two-dimensional temperature sensor by executing the storage control process only when the detection element is detected by the detection element at the end of each detection element The temperature satisfies the temperature condition, and image data for the pixel corresponding to this detection element (the pixel at the end in the temperature distribution image) (an image in which it is difficult to specify which part satisfies the temperature condition) Data) is stored in the storage unit, so that the pixel corresponding to the part having the temperature satisfying the temperature condition is located at the center of the temperature distribution image. Image data can be stored in the storage unit.

  Further, according to the temperature detection device of claim 3, the control unit displays, on the display unit, a temperature distribution image based on the image data stored in the storage unit when a preset warning display start condition is satisfied. By displaying the temperature distribution image displayed on the display unit, it is possible to easily identify which part is at a temperature satisfying the temperature condition.

  According to the temperature detection device of claim 4, the data generation unit emphasizes the pixel corresponding to the position of the detection element that has detected the temperature satisfying the temperature condition, and generates image data, thereby generating any part. Can be identified more easily whether the temperature satisfies the temperature condition.

  Furthermore, according to the temperature detection apparatus of claim 5, the data generation unit generates image data by emphasizing a predetermined number of pixels around the pixel corresponding to the position of the detection element that detects the temperature satisfying the temperature condition. By doing so, it is possible to more easily identify which part is at a temperature that satisfies the temperature condition, as compared with a temperature distribution image in which only one corresponding pixel is highlighted.

  The best mode of a temperature detection device and a temperature detection method according to the present invention will be described below with reference to the accompanying drawings.

  First, the configuration of the two-dimensional radiation thermometer 1 will be described with reference to the drawings.

  A two-dimensional radiation thermometer 1 shown in FIG. 1 is an example of a temperature detection device according to the present invention, and includes a sensor unit 2, a storage unit 3, an operation unit 4, a display unit 5, a buzzer 6, a data output unit 7, and a control. The unit 8 is provided so that the temperature of the temperature detection object can be detected according to the temperature detection method of the present invention. The sensor unit 2 is an example of a two-dimensional temperature sensor according to the present invention. As shown in FIG. 2, detection elements EAa to EPp (hereinafter also referred to as “detection element E” when not distinguished) are arranged to detect each of them. A sensor signal S1 indicating the temperature detected by the element E is output to the control unit 8. In the figure, in order to facilitate understanding of the present invention, the sensor unit 2 having a total of 256 detection elements E of 16 rows in the vertical direction and 16 rows in the horizontal direction is illustrated. As an example, a total of 4096 detection elements E of 64 columns in the vertical direction and 64 columns in the horizontal direction are arranged to constitute the sensor unit 2.

  In this case, as shown in FIG. 2, in the two-dimensional radiation thermometer 1, as an example, a determination region A is defined at the center of the temperature detection region where the detection elements EAa to EPp are arranged. When one of the detection elements E (144 detection elements ECc to ENn in the example of FIG. 1) outputs a sensor signal S1 indicating that a temperature exceeding the set value is detected, a warning sound is emitted. The configuration in which the image data D1 generated based on the sensor signal S1 is stored in the storage unit 3 is employed. The two-dimensional radiation thermometer 1 is configured so that the user can set the determination area A to an arbitrary size. In this case, it is preferable to define the size of the determination region A so that the ratio of the size of the determination region A to all of the detection elements EAa to EPp is in the range of 50% to 90%.

  The storage unit 3 stores reference value data D0 that can specify the temperature condition in the present invention, and stores image data D1 generated by the control unit 8 as described later. The operation unit 4 includes a start / stop switch for instructing start / end of a temperature measurement process 10 (see FIG. 3) to be described later, a numeric keypad for setting a temperature condition, a temperature condition satisfying the temperature condition (for example, a temperature higher than a set temperature) Various operation switches such as a display start switch for starting display of a temperature distribution image including a portion where temperature is detected and a display end switch (reset switch) for ending display of the temperature distribution image are provided ( Neither of them is shown), and an operation signal S2 corresponding to the switch operation is output to the control unit 8. The display unit 5 displays temperature distribution images P1 and P2 (see FIGS. 4 and 5) based on the image data D1 generated by the control unit 8. The buzzer 6 outputs a warning sound (buzzer sound) according to the control signal S3 output from the control unit 8. The data output unit 7 outputs the image data D1 stored in the storage unit 3 to an external device 9 (for example, a personal computer or a data collection device) under the control of the control unit 8.

  The control unit 8 comprehensively controls each unit of the two-dimensional radiation thermometer 1. The control unit 8 corresponds to the data generation unit in the present invention and the control unit in the present invention, and executes the temperature measurement process 10 shown in FIG. 3, and based on the sensor signal S1 output from the sensor unit 2, Image data D1 of the temperature distribution images P1 and P2 is generated and output to the display unit 5. In addition, the control unit 8 stores the temperature condition set by the numeric keypad operation of the operation unit 4 in the storage unit 3 as the reference value data D0 and is specified based on the reference value data D0 stored in the storage unit 3. When the sensor signal S1 having a temperature condition that satisfies the temperature condition (temperature exceeding the set temperature) is output from the sensor unit 2, both the display unit 5 and the storage unit 3 generate image data D1 generated based on the sensor signal S1. (Display of temperature distribution image P2 based on image data D1 and execution of storage control processing for storing image data D1 in storage unit 3) and output a control signal S3 to buzzer 6 to output a warning sound . In this case, in the two-dimensional radiation thermometer 1, the control unit 8 performs an averaging process on the sensor signal S1 output from the sensor unit 2 at predetermined time intervals, for example, ± 0.5 A configuration that cancels out small temperature changes within a range of about ° C is employed.

  Next, a method for using the two-dimensional radiation thermometer 1 will be described with reference to the drawings. In the following description, it is assumed that the temperature condition is set (defined) to “200 ° C. or higher” by operating the numeric keypad of the operation unit 4.

  First, the start / stop switch of the operation unit 4 is operated in a state where the sensor unit 2 is directed to the temperature detection target. At this time, the control unit 8 causes the sensor unit 2 to start outputting the sensor signal S1 in response to the operation signal S2 from the operation unit 4 (starts the temperature detection process), and the temperature shown in FIG. The measurement process 10 is started. In this temperature measurement process 10, the control unit 8 determines that the display start switch of the operation unit 4 is not operated (the warning display start operation is not performed) as described later (step 11), and the sensor unit. 2 and the reference value data D0 stored in the storage unit 3, the temperature detected by each detection element E in the determination area A is equal to or higher than a set temperature (in this example, 200 It is discriminated whether or not it is (° C. or higher) (step 12).

  At this time, when there is no heat generation part having a temperature equal to or higher than the set temperature in the direction in which the sensor unit 2 is directed, the control unit 8 generates image data D1 based on the sensor signal S1 output from the sensor unit 2 (step S1). 13) The generated sensor signal S1 is output to the display unit 5. Thereby, as shown in FIG. 4, the temperature distribution image P1 which shows the temperature detected by the sensor part 2 is displayed on the display part 5 (step 14). Note that pixels PAa to PPp (hereinafter also referred to as “pixels P” when not distinguished from each other) in FIG. 5 and FIG. 5 to be referred to later indicate pixels corresponding to the detection elements EAa to EPp of the sensor unit 2, respectively. Yes. In this case, in each figure, the pixel P shown in white indicates that the temperature is lower than the set temperature and is relatively low, and the pixel P indicated by the diagonally slanting left side is lower than the set temperature and is compared. The pixel P (see FIG. 5 and the like) indicated by a halftone line indicates that the temperature is higher than the set temperature. 4, 5, 8, and 9, the region Ap is a region of each pixel corresponding to each detection element E in the determination region A defined for the sensor unit 2 as described above (in the determination region A). Corresponding pixel area).

  On the other hand, when there is a heat generation part that is equal to or higher than the set temperature in the direction toward the sensor unit 2, the control unit 8 outputs the sensor signal S 1 output from the sensor unit 2 and the reference value data D 0 stored in the storage unit 3. Based on the above, it is determined that the temperature detected by a predetermined detection element E (for example, the detection element EHi shown in FIG. 2) in the determination region A is a temperature that satisfies the temperature condition (a temperature equal to or higher than the set temperature) ( An example of a state in which “a preset warning display start condition” in the present invention is satisfied: Step 12). Next, the control unit 8 generates image data D1 based on the sensor signal S1 output from the sensor unit 2 (step 15). At this time, the controller 8 detects the pixel P (in this example, the pixel PHi) corresponding to the position of the detection element E (in this example, the detection element EHi) that has detected a temperature equal to or higher than the set temperature, and the surrounding 8 In order to emphasize one pixel P (eight examples of the “predetermined number of pixels” in the present invention: in this example, eight pixels PGh to PGj, PHh, PHj, and PIh to PIj), these nine pixels P are Image data D1 that is blinked is generated.

  Next, the control unit 8 outputs the generated image data D1 to the display unit 5 to display the temperature distribution image P2 as shown in FIG. 5 (step 16), and to send a control signal S3 to the buzzer 6. The warning sound is output (step 17). As a result, the user who sees the temperature distribution image P2 displayed on the display unit 5 or hears a warning sound from the buzzer 6 has a heat generation portion exceeding the set temperature in the direction in which the sensor unit 2 is directed. Recognize Subsequently, the control unit 8 stores the generated image data D1 (image data of the temperature distribution image P2 shown in FIG. 5) in the storage unit 3 (step 18). Thereafter, the control unit 8 displays one of the temperature distribution images P1 and P2 shown in FIGS. 4 and 5 according to whether or not the temperature detected by the detection element E in the determination region A is equal to or higher than the set temperature. The processing (steps 14 and 16) to be displayed is continuously executed.

  In this case, in the above example, when the user hears a warning sound from the buzzer 6 but misses the temperature distribution image P2 displayed on the display unit 5, the user operates the display start switch of the operation unit 4. To do. At this time, the control unit 8 determines that the display start switch has been operated (warning display start operation has been performed) based on the operation signal S2 from the operation unit 4 (“warning display start condition in the present invention”). Another example of the state where “is satisfied: Step 11), it is determined whether or not the image data D1 is stored in the storage unit 3 (Step 19). At this time, for example, when the temperature equal to or higher than the set temperature is not detected until the time when the display start switch is operated, the image data D1 is not stored in the storage unit 3. The process after step 11 is executed.

  On the other hand, when the image data D1 is stored in the storage unit 3, the control unit 8 reads out the image data D1 from the storage unit 3 and outputs it to the display unit 5 as shown in FIG. P2 is displayed (step 20). As a result, a user who has missed the temperature distribution image P2 can refer to the temperature distribution image P2 based on the image data D1 stored in the storage unit 3. Thereafter, the control unit 8 monitors whether or not the reset switch of the operation unit 4 has been operated (step 21), and when the reset switch is operated, erases the image data D1 in the storage unit 3 ( Step 22), the processing after Step 11 is executed. Thereby, as described above, the display of the temperature distribution image P1 (step 14) or the display of the temperature distribution image P2 (step 16) is repeatedly executed.

  In the two-dimensional radiation thermometer 1, as described above, the temperature detected by the detection element E in the predetermined determination region A satisfies the temperature condition (in this example, the temperature equal to or higher than the set temperature (200 ° or higher). In the case of the temperature)), a warning sound is output from the buzzer 6 and the image data D1 of the temperature distribution image P2 is stored in the storage unit 3. In this case, a warning sound is output from the buzzer 6 and the temperature distribution image when the temperature detected by any of the detection elements EAa to EPp reaches a temperature condition without defining the determination area A. When adopting a configuration in which the image data D1 of P2 is stored in the storage unit 3, when using the two-dimensional radiation thermometer 1 in hand, for example, a part that does not satisfy the temperature condition (in this example, the set temperature is It may be somewhat difficult to specify the exothermic part.

  Specifically, when the two-dimensional radiation thermometer 1 is moved horizontally from the right side to the left side with respect to the heat generation site indicated by the temperature distribution image P2 shown in FIG. A warning sound is output from the buzzer 6 when the temperature detected by the detection element E located in the leftmost column (for example, the detection element EHa) reaches a temperature that satisfies the temperature condition (a temperature equal to or higher than the set temperature). Image data D1 based on the sensor signal S1 output from the sensor unit 2 at that time is stored in the storage unit 3. As a result, as shown in FIG. 6, the temperature distribution image P2x in which the pixel PHa corresponding to the detection element EHa and the surrounding pixel P in the above example are emphasized is displayed on the display unit 5, and as a result, Since the left side does not exist in the temperature distribution image P2x, it is difficult to specify the location of the heat generation part based on the temperature distribution image P2x.

  Similarly, when the two-dimensional radiation thermometer 1 is moved vertically from the lower side to the upper side with respect to the heat generation site indicated by the temperature distribution image P2 shown in FIG. A warning sound is output from the buzzer 6 when the temperature detected by the detection element E (detection element EPi as an example) located in the lowermost row becomes a temperature that satisfies the temperature condition (a temperature equal to or higher than the set temperature). At the same time, image data D1 based on the sensor signal S1 output from the sensor unit 2 is stored in the storage unit 3. As a result, as shown in FIG. 7, the temperature distribution image P2x in which the pixel PPi corresponding to the detection element EPi in the above example and the surrounding pixels P are emphasized is displayed on the display unit 5. Since the lower side does not exist in the temperature distribution image P2x, it is difficult to specify the location of the heat generation part based on the temperature distribution image P2x.

  On the other hand, in the two-dimensional radiation thermometer 1, the two-dimensional radiation thermometer 1 is moved horizontally from the right side to the left side with respect to the heat generation part indicated by the temperature distribution image P2 shown in FIG. For example, the temperature detected by the detection element E (in this example, the detection element EHc) located in the leftmost column in the determination region A in the sensor unit 2 satisfies a temperature condition (a temperature equal to or higher than the set temperature). ), A warning sound is output from the buzzer 6 and image data D1 based on the sensor signal S1 output from the sensor unit 2 at that time is stored in the storage unit 3. As a result, as shown in FIG. 8, the pixel PHc corresponding to the detection element EHc and the surrounding pixel P in the above example are emphasized, and a temperature distribution image P2 including most of the heat generation portion is displayed on the display unit 5. As a result of the display, it is possible to easily identify the location where the heat generating portion indicates.

  Further, in the two-dimensional radiation thermometer 1, when the two-dimensional radiation thermometer 1 is moved vertically from the lower side to the upper side with respect to the heat generation portion indicated by the temperature distribution image P2 shown in FIG. For example, the temperature detected by the detection element E (in this example, the detection element ENi) located in the lowermost row in the determination region A in the sensor unit 2 satisfies the temperature condition (a temperature equal to or higher than the set temperature). At that time, a warning sound is output from the buzzer 6 and the image data D1 based on the sensor signal S1 output from the sensor unit 2 at that time is stored in the storage unit 3. As a result, as shown in FIG. 9, the pixel PNi corresponding to the detection element ENi and the surrounding pixels P in the above example are emphasized, and a temperature distribution image P2 including most of the heat generation portion is displayed on the display unit 5. As a result of the display, it is possible to easily identify the location where the heat generating portion indicates.

  On the other hand, in the two-dimensional radiation thermometer 1, the image data D1 stored in the storage unit 3 is used instead of or together with the display on the display unit 5 of the temperature distribution image P2 for warning display as described above. Can be output to the external device 9. Specifically, when a warning sound is output from the buzzer 6 in step 17 of the temperature measurement process 10 described above, the image data D1 (temperature distribution for warning display) is operated by operating a predetermined switch of the operation unit 4. The output of the image P2 data) is instructed. At this time, the control unit 8 reads the image data D1 from the storage unit 3 according to the output of the operation signal S2 from the operation unit 4, and the read image data D1 is sent to the external device 9 via the data output unit 7. Output. Accordingly, the temperature distribution image P2 based on the image data D1 output from the two-dimensional radiation thermometer 1 can be displayed by the external device 9 (for example, a personal computer).

  As described above, according to the temperature detection method using the two-dimensional radiation thermometer 1 and the two-dimensional radiation thermometer, a plurality of detection elements E are arranged and a sensor signal S1 indicating the temperature detected by each detection element E is output. Based on the sensor signal S1 from the sensor unit 2, the image data D1 of the temperature distribution images P1 and P2 is generated, and a sensor signal indicating a temperature that satisfies a preset temperature condition (in this example, a temperature equal to or higher than the set temperature). A temperature at which any part satisfies a temperature condition by executing a storage control process in which image data D1 generated based on the sensor signal S1 is stored in the storage unit 3 when S1 is output Even if the distribution image P2 is missed, the missed temperature distribution image P2 is displayed on the display unit 5 based on the image data D1 stored in the storage unit 3. The heating portion has a degree satisfying temperature can be reliably and easily identified. Further, according to the temperature detection method using the two-dimensional radiation thermometer 1 and the two-dimensional radiation thermometer, the image data D1 is stored only when the temperature detected by any one of the detection elements E reaches a temperature condition. Image data D1 to be stored in the storage unit 3 as compared with a conventional measuring apparatus configured to store all of the temperature data output from the signal processing circuit in the memory by executing the storage control process stored in the unit 3 As a result, the storage unit 3 can be configured with a small-capacity memory as much as the amount of data required can be reduced. As a result, the manufacturing cost of the two-dimensional radiation thermometer 1 can be sufficiently reduced. In addition, since it is not necessary to search temperature data for abnormal heat generation sites from a large amount of temperature data, a desired temperature distribution image P2 can be easily displayed on the display unit 5 in a short time or output to the external device 9. Can be.

  Further, according to the two-dimensional radiation thermometer 1, a temperature satisfying the temperature condition (a temperature equal to or higher than the set temperature) from the detection element E in the determination area A defined in the central portion of the temperature detection area where the detection elements E are arranged. In a usage mode in which the two-dimensional radiation thermometer 1 is moved so as to change the direction of the sensor unit 2 by executing the storage control processing in the present invention only when the sensor signal S1 indicating (temperature) is output. The temperature detected by the detection element E at the end of each detection element E is a temperature that satisfies the temperature condition, and an image of the pixel P corresponding to this detection element E (the pixel P at the end in the temperature distribution image P2). The situation where the data D1 (the image data D1 in which it is difficult to specify which part is abnormally heated) is stored in the storage unit 3 is avoided, and the pixel P corresponding to the abnormally heated part is the temperature component. It is possible to store the image data D1 as positioned at the center of the image P2 in the storage unit 3.

  Further, according to the two-dimensional radiation thermometer 1, the control unit 8 generates the temperature distribution image P2 based on the image data D1 stored in the storage unit 3 when a preset warning display start condition is satisfied. By displaying on the display unit 5, it is possible to easily identify which part is generating abnormal heat by looking at the temperature distribution image P <b> 2 displayed on the display unit 5.

  Further, according to the two-dimensional radiation thermometer 1, the pixel corresponding to the position of the detection element E where the control unit 8 (the data generation unit in the present invention) has detected the temperature that satisfies the temperature condition (the temperature equal to or higher than the set temperature). By emphasizing P and generating the image data D1, it is possible to more easily identify which part is generating abnormal heat.

  Furthermore, according to the two-dimensional radiation thermometer 1, the pixel corresponding to the position of the detection element E where the control unit 8 (the data generation unit in the present invention) has detected the temperature that satisfies the temperature condition (the temperature equal to or higher than the set temperature). A temperature distribution image that highlights only one corresponding pixel P by generating image data D1 by emphasizing a predetermined number of pixels P around P (in this example, eight surrounding pixels P) In comparison, it can be more easily specified which part is abnormally heated.

  In addition, this invention is not limited to said structure. For example, the “temperature satisfying a preset temperature condition” in the present invention is not limited to the above “temperature equal to or higher than a preset temperature”. In this case, an image generated based on the sensor signal S1 when the sensor signal S1 indicating "temperature exceeding the preset temperature" is output as the "temperature satisfying the preset temperature condition" in the present invention. By adopting a configuration for executing the storage control process for storing the data D1 in the storage unit 3, the temperature satisfying the temperature condition is achieved in the same manner as the temperature detection method using the two-dimensional radiation thermometer 1 and the two-dimensional radiation thermometer. It is possible to reliably and easily identify the exothermic part.

  In addition, when the sensor signal S1 indicating "temperature lower than the preset temperature" or "temperature lower than the preset temperature" is output as the "temperature satisfying the preset temperature" in the present invention. By adopting a configuration for executing a storage control process for storing the image data D1 generated based on the sensor signal S1 in the storage unit 3, for example, the set temperature due to the fact that the equipment that should be operating is stopped When the temperature has not risen to this level, the facility that is not in operation can be identified reliably and easily. Furthermore, an image generated based on the sensor signal S1 when the sensor signal S1 indicating "a temperature within a preset temperature range" is output as the "temperature satisfying a preset temperature condition" in the present invention. By adopting the configuration for executing the storage control process for storing the data D1 in the storage unit 3, it is possible to reliably and easily identify the heat generating part that is at a temperature that satisfies the temperature condition and the equipment that is operating normally. An image generated based on the sensor signal S1 when the sensor signal S1 indicating "a temperature outside the preset temperature range" is output as the "temperature satisfying the preset temperature condition" in the present invention. By adopting the configuration for executing the storage control process for storing the data D1 in the storage unit 3, it is possible to reliably and easily specify both the high temperature abnormality and the low temperature abnormality.

  In the two-dimensional radiation thermometer 1, the temperature distribution image P2 based on the image data D1 is operated by operating the display start switch of the operation unit 4 in a state where the storage of the image data D1 in the storage unit 3 is completed. Is displayed on the display unit 5 and the state is maintained until the reset switch is operated. As an example, the temperature distribution image P2 is displayed on the display unit 5 in parallel with the storage of the image data D1. The temperature distribution image P2 can be maintained until the reset switch is operated. Furthermore, in order to emphasize the pixel P corresponding to the position of the detection element E that has detected a temperature condition that satisfies the temperature condition (for example, a temperature equal to or higher than the set temperature), and the eight surrounding pixels P, these nine pixels P are The example of generating the image data D1 that is displayed in a blinking manner has been described, but the method for emphasizing these pixels P is not limited to the blinking display. For example, a display color that is different from the other pixels P The method of emphasizing each pixel P described above can be employed by displaying the above. Of course, only the pixel P corresponding to the position of the detection element E that has detected the temperature condition (temperature equal to or higher than the set temperature) may be emphasized.

2 is a block diagram showing a configuration of a two-dimensional radiation thermometer 1. FIG. 3 is a plan view of a sensor unit 2. FIG. 5 is a flowchart of temperature measurement processing 10. It is a display screen figure which shows an example of the temperature distribution image P1 displayed by the two-dimensional radiation thermometer 1 in a normal state. It is a display screen figure which shows an example of the temperature distribution image P2 displayed by the two-dimensional radiation thermometer 1 at the time of warning. It is a display screen figure which shows an example of the temperature distribution image P2x displayed at the time of warning with another two-dimensional radiation thermometer. It is a display screen figure which shows another example of the temperature distribution image P2x displayed at the time of warning with another two-dimensional radiation thermometer. It is a display screen figure which shows another example of the temperature distribution image P2 displayed by the two-dimensional radiation thermometer 1 at the time of warning. It is a display screen figure which shows another example of the temperature distribution image P2 displayed by the two-dimensional radiation thermometer 1 at the time of warning.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Two-dimensional radiation thermometer 2 Sensor part 3 Memory | storage part 4 Operation part 5 Display part 6 Buzzer 7 Data output part 8 Control part 9 External device 10 Temperature measurement process A Judgment area Ap area D0 Reference value data D1 Image data P1, P2, P2x temperature distribution image EAa to EPp detection element PAa to PPp pixel S1 sensor signal S2 operation signal S3 control signal

Claims (6)

A two-dimensional temperature sensor in which a plurality of detection elements are arranged and outputs a sensor signal indicating a temperature detected by each detection element, and a data generation unit that generates image data of a temperature distribution image based on the sensor signal A temperature detecting device,
A storage unit for storing the image data;
A control unit for executing a storage control process for storing the image data generated based on the sensor signal when the sensor signal indicating the temperature satisfying a preset temperature condition is output in the storage unit; Equipped with a temperature detection device.   The control unit is only when the sensor signal indicating the temperature condition is output from the detection element in the determination region defined in the center of the temperature detection region in which the detection elements are arranged. The temperature detection apparatus according to claim 1, wherein the storage control process is executed. A display unit for displaying the temperature distribution image;
The said control part displays the said temperature distribution image based on the said image data memorize | stored in the said memory | storage part on the said display part when the preset warning display start conditions are satisfy | filled. Temperature detection device.   The temperature detection device according to claim 1, wherein the data generation unit generates the image data by emphasizing a pixel corresponding to a position of the detection element that detects a temperature that satisfies the temperature condition.   The temperature detection device according to claim 4, wherein the data generation unit emphasizes a predetermined number of pixels around the pixel corresponding to the position of the detection element that detects the temperature that satisfies the temperature condition, and generates the image data. .   Image data of the temperature distribution image is generated based on the sensor signal from the two-dimensional temperature sensor that outputs a sensor signal indicating the temperature detected by each of the plurality of detection elements arranged in advance. A temperature detection method for storing, in a storage unit, the image data generated based on the sensor signal when the sensor signal indicating the temperature satisfying the temperature condition is output.

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