JP2014002430A - Facility inspection system and measuring instrument for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a facility inspection system capable of eliminating failures such as data mismatching when an inspection operator patrols facilities, acquires image data and utilizes the acquired image data for facility inspection, and capable of reducing cost and operation loads of image processing, and to provide a measuring instrument for the facility inspection system.SOLUTION: The facility inspection system comprises: an image database 31 for storing image data including a display part for displaying a measurement result of the measuring instrument and a facility to be measured by the measuring instrument; image processing means 32 having a function for processing the image data of the image database and reading measurement values in the image data and a function for specifying the facility to be measured; inspection management means 33 having a function for determining soundness of the facility to be measured based on the result of the image processing means; and display means 35 for displaying a result of the inspection management means.

Description

  The present invention relates to an equipment inspection system that performs image processing of image data and inspects and manages equipment based on the image processing result, and a measuring instrument therefor.

  As a method of inspecting the equipment, there is a method in which an inspection worker patrols and records the result. In this method, it has been a problem to prevent reading errors and transcription errors of inspection workers. There is a method of utilizing image data for the purpose of reducing reading errors and transcription errors of inspection workers or automating and unmanned inspections.

  Patent Document 1 describes a method related to positioning of a camera when a camera moves instead of an inspection worker and photographs a plurality of points to automate reading of an indicator.

  Patent Document 2 describes a method of acquiring the RFID tag information at the time of image capturing by inputting the feature of the inspection target equipment and the numerical value reading information of the measuring instrument to the RFID tag in order to reduce the calculation load of the image processing. ing.

  Reference 2 is cited.

Japanese Patent No. 3468255 Japanese Patent No. 4670434

  In Patent Document 1, since the measuring instrument does not move and only the camera moves, in order to use the measurement data of the inspection target equipment as the inspection result, a measuring instrument is required for each equipment, which may increase the cost.

  In Patent Document 2, transmission / reception means to / from the RFID tag is required in addition to the image processing means, which may increase the cost. In addition, RFID tags and barcodes are provided, but only information indicating the characteristics of the measuring instrument is used, and the use of the measuring instrument for the measurement result and the consistency between the measurement result of the measuring instrument and the measurement target equipment are not considered. .

  SUMMARY OF THE INVENTION An object of the present invention is to provide an equipment inspection system and a measuring instrument therefor that can eliminate the problem of data inconsistency when utilizing image data for equipment inspection, reduce the calculation load of image processing at low cost.

  In order to solve the above-described problem, in the equipment inspection system of the present invention, a display unit that displays the measurement result of the measuring instrument, an image database that stores image data including the measurement target equipment of the measuring instrument, and the image database An image processing unit having a function of processing the image data and reading a measurement value in the image data and a function of specifying the measurement target facility, and a soundness level of the measurement target facility based on a result of the image processing unit It is characterized by comprising inspection management means having a determination function and display means for displaying the result of the inspection management means.

  The image data includes a symbol representing a display format of a measurement result of the measuring instrument, and the image processing means reads the image data.

  The measuring instrument has a function of converting a measurement result into a two-dimensional code and displaying it on the display unit, and a function of the image processing means reading the two-dimensional code of the display unit and acquiring information.

  Further, the image database stores image data including an equipment two-dimensional code representing the characteristics of the measurement target equipment, and the image processing means has a function of reading the equipment two-dimensional code.

  The measuring instrument is portable.

  The measurement item of the measuring instrument is characterized by converting position information and / or time information into a two-dimensional code and displaying it.

  Furthermore, in order to solve the above problems, the measuring instrument of the present invention includes one or more sensors, signal processing means for converting the signals of the sensors into measurement values, and measurement information of the signal processing means in a two-dimensional code. It comprises a two-dimensional code creating means for conversion, and a display means for switching and displaying either or both of the measured value of the signal processing means and the two-dimensional code of the two-dimensional code creating means.

  The measuring instrument is portable.

  According to the present invention, an inspection worker patrols equipment to acquire image data, eliminates the problem of data inconsistency when the acquired image data is used for equipment inspection, and reduces the calculation load of image processing at low cost. An equipment inspection system and its measuring instrument that can be realized are realized.

It is a figure which shows the Example of the measuring device used for this invention. It is a figure which shows the system configuration | structure of the measuring device of this invention. It is a figure which shows the system configuration | structure of the equipment inspection system of this invention. It is one Example of the image data of this invention. It is another Example of the image data of this invention. It is another Example of the image data of this invention. It is a figure which shows the processing flow of the equipment inspection system of this invention. It is a figure which shows the other processing flow of the equipment inspection stem of this invention. It is a figure which shows the other processing flow of the equipment inspection stem of this invention.

  FIG. 1 shows a measuring instrument for constituting an embodiment of the present invention. Sensors 1-1 to 1-4 in FIG. 1 are provided with sensors (not shown), and the signals from the sensors are processed to display measured values. Sensors include temperature, humidity, water quality (pH, turbidity, chromaticity, organic matter, nitrogen, phosphorus, suspended matter, etc.), vibration, acceleration, sound, location information, time, etc. May be provided. The measured values of the sensors are displayed on the display screens 11-1 to 11-4. The display method of the measurement result includes a numerical value (11-1), a pointer (11-2), a waveform (11-3), a two-dimensional code (11-4), and the like. In addition, display format labels 12-1 to 12-4 representing the display formats of the respective measurement results are installed in the measuring instruments 1-1 to 1-4.

  FIG. 2 shows a system flow of a measuring instrument that displays a measurement result as a two-dimensional code. Signals from the sensors 20-1 to 20-3 are sent to the sensor signal processing means 21, which converts the sent sensor signals into measured values and sends them to the display means 23 as signals. The display means 23 displays the measured value. Further, the sensor signal processing means 21 sends the processing result to the two-dimensional code creation means 23, the two-dimensional code creation means 23 transmits the information of the created two-dimensional code to the display means 22, and the display means 22 outputs the measured value to the two-dimensional code. Can be displayed as a dimension code. The display means 22 can display both or one of the measured value and the two-dimensional code, and has a function of switching the display. In this embodiment, an example is shown in which there are three sensors, but there is no limit on the number.

  FIG. 3 shows a system flow of the equipment inspection system of the present invention. The image database 31 stores image data taken during equipment inspection. The image data can be automatically updated by either wired or wireless. Although not shown, the image data of the image database 31 is sent to the image processing means 32 by a control signal of the equipment inspection system. In the image processing, the image processing means 32 obtains information on the display format labels 12-1 to 12-4 of the measuring instrument from the display format label database 36, processes the image data, and extracts information on the measurement target equipment and the measured value. To the inspection management means 33. The inspection management means 33 obtains information on measured values for the past measurement target equipment from the inspection database 34. The inspection management means 33 compares the current value obtained from the image processing means 32 with the past data in the inspection database 34, and determines the degree of soundness. The inspection management means 33 sends the measurement value and determination result of the target equipment to the result display means 35, and the result display means 35 displays the result as the inspection result of the target equipment. Moreover, when the inspection result is determined to be abnormal, the inspection management means 33 preferably sends an alarm signal to another system. Further, the inspection management means 33 may make the determination using information such as an operation history, a failure history, an operation amount, a purchase history, and a maintenance history of the target equipment at the time of comparison and determination.

  FIG. 4 shows an embodiment of image data stored in the image database 31 of the present invention. The image of a present Example is preserve | saved as the same image as the measurement object equipment 41, and the display screen of the measured value of the electric motor for water supply and the measuring device 1-1. The measuring instrument 1-1 is provided with a display unit 11-1 that displays the result of the measurement value and a display format label 12-1 that represents the display format.

  An inspection method for the equipment inspection system of the present invention will be described.

  FIG. 7 shows a processing flow of the equipment inspection system of the present invention. The equipment inspection system first sends the image data of the image database 31 to the image processing means 32 in step 1 and reads the image data.

  Next, in step 2, the image processing means 32 reads the display format label 12-1 and the display format label data of the measuring instrument from the display format database 36.

  Next, in step 3, the information of the read label data is analyzed to determine the measurement item. Measurement items are set in advance for each display format label 12-1 and can be determined by referring to the display format database 36.

  Next, the information of the label data read in step 4 is analyzed, and the display format of the display means of the measuring instrument is determined based on the information in the display format database 36. As shown in FIG. 1, the display format includes a numerical format, a pointer format, a waveform format, and a two-dimensional code format.

  Next, in step 5, the measurement result of the display unit of the measuring instrument is read. In the case of the numerical format, since recognition is performed on the assumption that the image data is a numerical value, erroneous recognition can be reduced. In the case of the pointer type, the angle θ (see FIG. 1) with the pointer 13 is read with the bottom of the display screen 11-2 as the reference line. When the display format is a waveform, the maximum value (a) and the minimum value (b) of the waveform are recognized (see FIG. 1). It is good also as the number of local maximum value, local minimum value, and an average value as needed. When the display format is a two-dimensional code, it is read according to a preset code format.

  Next, in step 6, the measured value is recognized as a numerical value. When the display format is a numeric format, the read value is recognized as a measured value. In the case of the pointer type, the angle θ is converted into a numerical value according to a preset coefficient. When the coefficient is different for each measuring instrument, the coefficient information may be changed according to the measuring instrument display label 12-2, and the coefficient information may be changed based on the determination result of the display format in Step 4. When the display format is a waveform, it may be converted to a maximum value, minimum value, average value, frequency, or the like. When the display format is a two-dimensional code, a numerical value is read from the code.

  Next, the equipment inspection system reads the image data of the part other than the measuring instrument in step 7.

  Next, in step 8, the characteristics of the equipment to be measured are extracted. As the characteristics of the equipment, the aspect ratio, the connection angle of parts, the dimensions etc. are specified based on the measuring instrument. In order to improve the feature extraction accuracy, the image shooting position may be fixed. Further, a reference part may be provided, the amount of reflection of the reference part may be defined at the time of shooting, and the shooting position may be fixed.

  Next, in step 9, the inspection database 34 is read, and information indicating the characteristics of the equipment input in advance is obtained.

  Next, in step 10, the facility in which the feature of the facility obtained in step 8 matches the feature of the facility obtained in step 9 is extracted.

  Next, in step 11, the information on the measurement target equipment obtained in step 10, the measurement item information obtained in step 3, and the measurement value information obtained in step 6 are combined. Value data.

  Next, in step 12, the difference amount and the change rate between the current value obtained in step 11 and the past data (previous value or initial value) of the target facility accumulated in step 9 are calculated and used as a comparison result. .

  Next, in step 13, the soundness level is determined based on the relationship between the comparison result obtained in step 12 and the soundness level set in advance.

  Next, in step 14, the current value in step 11 and the soundness determination result obtained in step 13 are displayed. In addition, an alarm is output when the soundness level becomes a predetermined value or less.

  Next, in step 15, the result of step 14 is stored in the inspection database 34, and the process ends.

  The processing flow of the equipment inspection system described above is started when the database of the image database 31 is updated. Moreover, you may start at the time set to the equipment inspection system.

  According to the present invention, since the display of the inspection target equipment and the measurement values thereof are the same image data, the inspection worker circulates the equipment to acquire the image data, and by analyzing the acquired image data, Since the equipment to be inspected and the measured values can be obtained, it is possible to reduce inconsistencies in data inconsistency. In addition, the measuring instrument may be portable, and only image processing is required, so the cost can be reduced. Further, since image processing is performed after determining the display format of the measuring instrument, it is possible to reduce misrecognition and reduce the calculation load. Furthermore, since the measuring instrument and the measurement target equipment are in the same image, it is possible to verify the presence or absence of an inspection crew's patrol error.

  FIG. 8 shows a processing flow of another embodiment of the present invention. In this embodiment, the measuring instrument in the image data is the measuring instrument 1-4 and the display format is limited to the two-dimensional code. The two-dimensional code incorporates information such as measurement items, measurement values, position information, and time of the measuring instrument. The difference between the present invention and the embodiment of FIG. 7 is the difference from step 4 to step 6-1. Hereinafter, differences will be described.

  In step 4, the equipment inspection system recognizes that the instrument display label 12-4 is a two-dimensional code.

  Next, the two-dimensional code is read in step 5, and information such as measurement items and measurement values is recognized in step 6-1 and sent to step 11. In addition, when the location information is included, the equipment inspection system can be used as data when the equipment is specified in step 10.

  According to the present invention, since a two-dimensional code including a plurality of pieces of information is used, a plurality of items such as measurement items and measurement values can be processed at the same time, thereby reducing data inconsistency and reducing image processing load. In addition, when an inspection worker circulates equipment to acquire image data, the acquired image data is analyzed, and the equipment to be inspected and its measurement value are acquired, a portable measuring instrument may be used, and only image processing is required. The cost can be reduced because it is good.

  FIG. 5 shows image data of another embodiment of the present invention. The difference from the embodiment of FIG. 4 is that one or both of an equipment name label 51 and an equipment code label 52 of a two-dimensional code representing equipment characteristics are attached to the equipment 41 to be measured, and one or more of these are measured as image data. Stored together with the device 1-1.

  FIG. 9 shows a processing flow of an equipment inspection system according to another embodiment of the present invention. The difference from the embodiment of FIG. 7 is in the method of specifying the measurement target equipment in steps 7 to 10 in FIG.

  In the present invention, the equipment inspection system first reads image data in step 1. Next, in step 30, information on the equipment code label 52 is read. The label information read in step 31 is subjected to image processing, and the obtained information, such as a device number, is sent to step 11 as a feature of the measurement target facility.

  According to the present invention, the equipment to be measured can be specified without collating with the inspection database, and can be implemented only by image processing, so that it is possible to reduce data inconsistency and reduce the calculation load for equipment specification. In addition, the inspection operator can use the portable measuring instrument to go around the facility to acquire the image data, and the facility inspection can be easily realized by analyzing the acquired image data, so that the inspection cost can be reduced.

  FIG. 6 shows image data of another embodiment of the present invention. While displaying one or both of the equipment name label 51 of the equipment to be measured and the equipment code label 52 representing the characteristics of the equipment as compared with the above-described embodiment on the measuring instrument photographing board 61 installed in the vicinity of the equipment, You may preserve | save the measuring device 1-1 of object collectively. By using the image data in which the measuring instrument 1-1 is installed in front of the measuring instrument photographing board 61, it is possible to reduce blurring of the image due to the difference in distance between the measurement target equipment and the measuring instrument. Further, since the background can be defined, it is possible to reduce the calculation load of image processing.

1-1 to 1-4 Measuring Instruments 11-1 to 11-4 Display Units 12-1 to 12-4 Display Format Label 13 Hands 20-1 to 20-3 Sensor 21 Sensor Heart Transit Processing Unit 22 Display Unit 23 Two-dimensional Code creation means 31 Image database 32 Image processing means 33 Inspection management means 34 Inspection database 35 Result display means 36 Display format label database 41 Measurement object equipment 51 Equipment name label 52 Equipment code label 61 Measuring instrument photographing board

Claims (8)

A display unit for displaying the measurement result of the measuring instrument, and an image database for storing image data including the measurement target equipment of the measuring instrument,
Image processing means having a function of processing the image data of the image database and reading a measurement value in the image data and a function of specifying the measurement target equipment;
Inspection management means having a function of judging the soundness of the measurement target equipment based on the result of the image processing means;
Display means for displaying the results of the inspection management means;
An equipment inspection system characterized by comprising: In claim 1,
The image data contains a symbol representing the display format of the measurement result of the measuring instrument,
The equipment inspection system, wherein the image processing means reads the image data. In claim 1 or claim 2,
A function for the measurement device to convert a measurement result into a two-dimensional code and display it on the display unit;
The image processing means reads the two-dimensional code of the display unit and acquires information;
An equipment inspection system characterized by comprising: In claims 1 to 3,
The image database stores image data including an equipment two-dimensional code representing the characteristics of the equipment to be measured,
The equipment inspection system, wherein the image processing means has a function of reading the equipment two-dimensional code. In claims 1 to 4,
The equipment inspection system, wherein the measuring instrument is portable. In claim 5,
The equipment has a function of converting position information and / or time information as a measurement item into a two-dimensional code and displaying it. One or more sensors;
Signal processing means for converting the signal of the sensor into a measured value;
Two-dimensional code creating means for converting the measurement information of the signal processing means into a two-dimensional code;
Display means for switching and displaying the measured value of the signal processing means, both or one of the two-dimensional codes of the two-dimensional code creating means,
A measuring instrument characterized by comprising. In claim 7,
The measuring instrument is portable.