JPH06241951A - Diagnosys of overheat of electric apparatus - Google Patents

Abstract

PURPOSE:To rationalize a diagnosis of overheat by preparing an image for the diagnosis of overheat by applying a marking processing to the part of an infrared heat image of an electric apparatus of which the temperature exceeds a control temperature. CONSTITUTION:A control temperature Tc corresponding to a load factor K at the time when a heat image 5c is picked up is computed from an allowable temperature rise standard value of an apparatus to be diagnosed. This temperature Tc is displayed on a color bar 5b as a control temperature level on a heat image photograph 5A. Besides, the part of the heat image 5c exceeding this control temperature level is marked with oblique lines as an overheat danger area. In the case when a diagnosis of overheat of the apparatus of power receivingtransforming equipment is executed on the basis of the heat image 5c, accordingly, the temperature Tc being a rise value of an allowable temperature of the apparatus of the power receiving-transforming equipment is introduced and displayed on the heat image 5c picked up at an arbitrary load and thereby a rational and reasonable diagnosis of overheat of an electric apparatus can be executed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for diagnosing overheating of electrical equipment, such as power receiving and transforming equipment, by diagnosing the overheating state of the electrical equipment with infrared thermal images.

[0002]

2. Description of the Related Art A conventional overheat diagnosing method for electric equipment will be described with reference to FIGS. FIG. 6 is a diagram showing an outline of a conventional overheat diagnosis method for electric equipment. Also,
FIG. 7 is a thermal image photograph (FIG.) Obtained by a conventional overheat diagnosis method for electric equipment.

In FIG. 6, reference numeral 1 denotes a device to be diagnosed such as a power receiving and transforming device, which is a device body case 1a and a bushing 1b.
And a terminal connecting portion 1c. Reference numeral 2 is a high-voltage bus bar of the electric room, and 3 is a connection lead to the device under diagnosis 1.

Further, in FIG. 6, reference numeral 4 denotes an infrared thermal image pickup device (infrared camera), which comprises a camera body 4a having a built-in camera controller and the like, and a tripod 4b for supporting and adjusting the position of the camera body 4a. Has been done.

In FIG. 7, reference numeral 5 is a thermal image photograph (figure) obtained by the infrared thermal image capturing device 4, which comprises a numerical display 5a, a color bar 5b and a thermal image 5c. The numerical display 5a has an optimally adjusted maximum set temperature Tmax and minimum adjusted temperature Tmin.
In addition, the ambient temperature Tamb at the time of image capturing, the distance D to the device 1 to be diagnosed, the emissivity ε of the device 1 to be diagnosed, the image capturing date, and other image capturing parameters are displayed. Also, thermal image 5
c is the minimum set temperature Tmin to the maximum set temperature Tmax
Are displayed in color with the color bar 5b having 128 gradations.

However, in the thermal image photograph 5, although the thermal image 5c itself of the device to be diagnosed 1 is obtained as a clear color photograph, there is no judgment level depending on the allowable temperature of the device to be diagnosed 1 It has a drawback that it is not persuasive as a thermal image photograph for overheat diagnosis.

That is, in the case of performing overheat diagnosis due to secular change or poor contact in the operating state of power receiving and transforming equipment, a thermal image is taken using an infrared camera. In order to determine the overheat in this case, there is no method for evaluating the thermal image of an arbitrary load by comparing it with the temperature rise standard value at the rated load.

[0008]

In the conventional overheat diagnosing method for electric equipment as described above, since the thermal image photograph 5 does not have a judgment level based on the allowable temperature of the equipment under diagnosis 1, the overheat diagnosis for the equipment under diagnosis 1 is made. There was a problem that it was not persuasive as a thermal image photograph.

The present invention has been made in order to solve the above-mentioned problems, and since the management temperature which is a standard for overheat diagnosis is introduced and posted, the overheat diagnosis can be rationalized and the persuasiveness can be enhanced. It is an object of the present invention to obtain an overheat diagnosis method for an electric device capable of performing the above.

[0010]

A method for diagnosing overheat of an electric device according to claim 1 of the present invention includes the following steps. [1] A control temperature calculation step of obtaining a control temperature corresponding to the type of the electric device based on a permissible temperature rise specification value of the electric device and ambient conditions. [2] For overheat diagnosis by clearly indicating the control temperature and comparing the infrared thermal image data of the electric device with the control temperature to perform marking processing on the infrared thermal image portion of the electric device which exceeds the control temperature. Image creation step to create the image of.

An overheat diagnosing method for electric equipment according to a second aspect of the present invention includes the following steps. [1] An image conversion step of converting infrared thermal image data under an arbitrary load of an electric device into infrared thermal image data under a rated load. [2] A control temperature calculation step of obtaining a control temperature corresponding to the type of the electric device based on a permissible temperature rise specification value of the electric device and ambient conditions. [3] For overheat diagnosis by clearly indicating the control temperature, comparing the infrared thermal image data of the electric device with the control temperature, and marking the infrared thermal image portion of the electric device that exceeds the control temperature to perform overheat diagnosis. Image creation step to create the image of.

[0012]

In the overheat diagnosing method for electric equipment according to the first aspect of the present invention, the control temperature calculating step comprises the control temperature corresponding to the type of the electric equipment based on the allowable temperature rise standard value of the electric equipment and the ambient conditions. Is required. In the image creating step, the control temperature is clearly indicated, and the infrared thermal image data of the electric device is compared with the control temperature, and the infrared thermal image portion of the electric device that exceeds the control temperature is marked. Then, an image for overheat diagnosis is created.

In the overheat diagnosis method for an electric device according to the second aspect of the present invention, the infrared thermal image data at an arbitrary load of the electric device is converted into the infrared thermal image data at the rated load in the image conversion step. Further, in the control temperature calculation step, the control temperature corresponding to the type of the electric device is obtained based on the allowable temperature rise standard value of the electric device and the ambient condition. Further, in the image creating step, the control temperature is clearly indicated, and the infrared thermal image data of the electric device is compared with the control temperature, and the infrared thermal image portion of the electric device which exceeds the control temperature is subjected to marking processing. Then, an image for overheat diagnosis is created.

[0014]

【Example】

Example 1. Example 1 of the present invention is a conventional thermal image photograph 5
It covers the judgment part of overheat diagnosis, which is not convincing. Therefore, the method itself for photographing the thermal image photograph (FIG.) Itself is the same as that shown in FIG. However, when processing a floppy disk containing thermal image information by the infrared thermal image capturing device 4 on site, for example, by a personal computer in an office, a process process for determining overheat diagnosis is performed, and this is incorporated into a thermal image photograph. It is characterized by that.

FIG. 1 shows a diagnostic algorithm for performing a process process of determining overheat diagnosis according to the first embodiment of the present invention.
This will be described with reference to FIGS. 2 and 3. 1 and 2
3 is a flowchart showing a first embodiment of the present invention.
Further, FIG. 3 is a diagram showing the types of devices to be diagnosed. In each figure, the same reference numerals indicate the same or corresponding parts.

In step 10 of FIG. 1, the control temperature Tc is determined according to the type by a predetermined calculation formula described later.

In step 11, the thermal image data is taken out from the floppy disk pixel by pixel. Temperature data is attached to each pixel of the thermal image.

In step 12, the temperature data of the thermal image data is compared with the control temperature Tc determined by the type of the device to be diagnosed 1 as described later, and if it is higher than or equal to the control temperature, the process proceeds to the marking process in step 13. When the temperature is lower than the control temperature, the normal processing of step 14 is performed.

In steps 13 to 14, if the temperature is higher than the control temperature, marking processing is carried out, and in other cases, normal processing is carried out. That is, as shown in the thermal image photograph 5A of FIG. 4, as the control temperature Tc in the numerical display 5a, the allowable temperature rise standard value Qn is converted into a temperature corresponding to the load factor K of the device during thermal image capturing. indicate. Further, in the color bar 5b, the control temperature Tc is clearly shown in black or white, and in the thermal image 5c, a portion exceeding the control temperature Tc is displayed by marking, for example, FIG.
It is displayed in the same color as the control temperature as shown by the shaded area.
Therefore, the overheated portion of the device can be determined at a glance.

In step 15, it is judged whether or not the processing in steps 11 to 14 has been performed for all the taken out thermal image data, and when the above processing is completed for all the data, the processing is stopped.

In step 20 of FIG. 2, the type of the device under diagnosis 1 is determined. There are the following three categories in the form of heat generation of the substation equipment that is the equipment to be diagnosed 1. First, type A that generates heat regardless of the load condition. In addition, as Type B, heat generation changes in response to the load condition. And type A and B as type C
There is a mixed form of. That is, the device to be diagnosed is classified into three types of type A, type B and type C shown in FIG. 3 according to the heat generation factor, and the control temperature of each type is obtained.

When the type A is connected as a power receiving and transforming equipment, the internal heat loss as the equipment does not depend on the fluctuation of the load power. The power factor improving phase advancing capacitor and its series reactor are connected to a parallel circuit irrelevant to the load current, and therefore belong to this type A. Also, in the transformer PT for instruments, since the secondary load does not change once it is connected, it also belongs to type A.

Since the type B is connected in series with the main trunk line as a power receiving and transforming equipment circuit, the internal heat loss of the device depends on the fluctuation of the load power. The disconnector, circuit breaker, instrument transformer CT, power fuse and their terminal connections belong to type B.

The type C is a mixture of a loss unrelated to the load current such as iron loss as internal heat generation and a loss dependent on the load current such as copper loss and eddy current loss. Power transformers belong to this type C.

In Steps 21 to 22, the control temperature Tc of the type A is the converted temperature increase standard value Qa and the ambient temperature T.
Obtained from amb, it becomes as shown in the following equation.

Tc = Qa + Tamb = f ₁ + Tamb

In the case of type A, since the converted temperature rise standard value Qa = f ₁ and the allowable temperature rise standard value Qn are the same,
It becomes as shown in the following formula. Here, the allowable temperature rise standard value Q
n is the temperature rise standard value when the load factor K = 1,
It is a value determined by JIS etc. and is a value obtained by dividing the total loss of the device by the no-load loss.

Tc = Qn + Tamb

In steps 23 to 24, the control temperature Tc of type B is the converted temperature increase standard value Qb and the ambient temperature T.
Obtained from amb, it becomes as shown in the following equation.

Tc = Qb + Tamb = f ₂ (K) + Tamb

Further, in the case of type B, the converted temperature rise standard value Qb = f ₂ (K) is obtained from the allowable temperature rise standard value Qn and the load factor K, and is given by the following equation. The function f ₂ (K) is set based on experimental data in the factory of the device.

Tc = QnK ^0.8 + Tamb

In steps 25 to 26, the control temperature Tc of the type C is the converted temperature rise standard value Qc and the ambient temperature T.
Obtained from amb, it becomes as shown in the following equation.

Tc = Qc + Tamb = f ₃ (K, R) + Tamb

In the case of type C, the converted temperature rise standard value Qc = f ₃ (K, R) is calculated from the allowable temperature rise standard value Qn, the load factor K, and the equipment loss R (= load loss / no load loss). It is calculated as shown in the following equation. The function f ₃ (K,
Similarly to the function f ₂ (K), R) is set based on experimental data in the factory of the device.

Tc = Qn {(1 + RK ² ) / (1+
R)} ^0.8 + Tamb

By the way, the control temperature calculating step according to the present invention is the step 1 in the first embodiment of the present invention described above.
0, that is, steps 20 to 26, and the image creating steps according to the present invention are steps 11 to 1 in the first embodiment.
Equivalent to 5.

The first embodiment of the present invention, as described above,
The control temperature Tc corresponding to the load factor K at the time of thermal image capturing is calculated from the allowable temperature rise standard value (Qn when the load factor K = 1) of the device to be diagnosed 1, and the control temperature Tc is used as the thermal image photograph 5.
The control temperature level on A is displayed on the color bar 5b. Further, the thermal image portion exceeding the control temperature level is marked (hatched portion) as an overheating risk area.

That is, the power receiving and transforming equipment is divided into three types A, B and C according to the load dependency of the internal heat generation, and the management temperature Tc after the temperature conversion processing according to the diagnostic algorithm is performed for each division. By contrast, overheat diagnosis is performed accurately.

The control temperature value Tc corresponding to the load factor at the time of photographing is clearly indicated on the color bar 5b and the numerical display 5a on the thermal image photograph 5A, and the thermal image portion of the electric equipment exceeding this control level is regarded as an abnormal portion. Marking (hatched part)
Give.

Therefore, in the case of diagnosing the overheat of the power receiving and transforming equipment by using the infrared thermal image, the management temperature Tc which is the allowable rise value of the temperature of the power receiving and transforming equipment is introduced on the thermal image taken under an arbitrary load. Therefore, it is possible to provide a rational and highly convincing method for diagnosing overheat of an electric device.

Example 2. In the second embodiment, as shown in the thermal image photograph 5B of FIG. 5, for example, the load factor K = 0.45.
The color bar 5b and the thermal image 5c photographed in (3) are converted into a load factor K = 1.0 as shown on the right side of FIG. The logical expression of the conversion at this time is the functions f ₂ and f ₃ described in the first embodiment.
Comply with. Control temperature Tc = Qn + for color bar 5d
Tamb is displayed, and the overheated portion exceeding the control temperature Tc is marked on the thermal image 5e converted into the load factor K = 1.0.

That is, a thermal image of an electric device taken at an arbitrary load is converted into a thermal image at a rated load, and the allowable temperature of the electric device is clearly indicated as a control level on the color bar 5d on the converted thermal image. The thermal image part of the electrical equipment that exceeds the control level was marked as an abnormal part (hatched part).

The second embodiment of the present invention, as described above,
The temperature of each part of the equipment surface is converted into a rated load with a load factor K = 1 from the thermal image capture result (load factor K) of the device to be diagnosed 1, and this is adopted as the thermal image at the rated load. Further, the management temperature Tc is displayed on the converted thermal image, and the thermal image portion exceeding the management temperature level is marked as an overheating risk area. Therefore, overheat diagnosis can be performed without operating at the rated load. In other words, it is possible to estimate the overheated state at the rated load.

[0045]

As described above, the method for diagnosing overheat of an electric device according to claim 1 of the present invention is based on the allowable temperature rise specification value of the electric device and the ambient conditions, and the control temperature according to the type of the electric device. And a management temperature calculation step for determining the management temperature, comparing the infrared thermal image data of the electric device with the management temperature, and marking the infrared thermal image portion of the electric device exceeding the management temperature. Since the image forming step of forming an image for overheat diagnosis by applying the above is included, there is an effect that the overheat diagnosis can be rationalized and persuasiveness can be increased.

As described above, the method for diagnosing overheat of an electric device according to a second aspect of the present invention comprises an image conversion step of converting infrared thermal image data under an arbitrary load of the electric device into infrared thermal image data under a rated load, A control temperature calculating step for obtaining a control temperature according to the type of the electric device based on a permissible temperature rise standard value of the electric device and ambient conditions; and an infrared thermal image data of the electric device, which clearly indicates the control temperature. An image creating step of creating an image for overheat diagnosis by performing a marking process on the infrared thermal image portion of the electric device that compares the management temperatures and exceeds the management temperature, so that the overheat diagnosis can be rationalized. In addition, it is possible to increase the persuasiveness and to estimate the overheated state at the rated load.

[Brief description of drawings]

FIG. 1 is a flowchart showing the overall operation of Embodiment 1 of the present invention.

FIG. 2 is a flowchart showing a control temperature calculation operation according to the first embodiment of the present invention.

FIG. 3 is a diagram showing types of devices to be diagnosed according to the first embodiment of the present invention.

FIG. 4 is a diagram showing a thermal image photograph of Example 1 of the present invention.

FIG. 5 is a diagram showing a thermal image photograph of Example 2 of the present invention.

FIG. 6 is a diagram showing an outline of a conventional overheat diagnosis method for an electric device.

FIG. 7 is a diagram showing a thermal image photograph of a conventional overheat diagnosis method for electric devices.

[Explanation of symbols]

 1 Device to be diagnosed 4 Infrared thermal imaging device 5A, 5B Thermal image photograph 5a Numerical display 5b Color bar 5c Thermal image 5d Color bar 5e Thermal image after image conversion

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[Procedure amendment]

[Submission date] February 25, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0023

[Correction method] Change

[Correction content]

Since the type B is connected in series with the main trunk line as a power receiving and transforming equipment circuit, the internal heat loss of the device depends on the fluctuation of the load power. The disconnector, circuit breaker, current transformer CT, power fuse and their terminal connections belong to type B.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Name of item to be corrected] 0027

[Correction method] Change

[Correction content]

In the case of type A, since the converted temperature rise standard value Qa = f ₁ and the allowable temperature rise standard value Qn are the same,
It becomes as shown in the following formula. Here, the allowable temperature rise standard value Q
n is the temperature rise standard value when the load factor K = 1,
It is a value determined by JIS or the like.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0035

[Correction method] Change

[Correction content]

In the case of type C, the converted temperature rise standard value Qc = f ₃ (K, R) is calculated from the allowable temperature rise standard value Qn, the load factor K, and the equipment loss R ( total loss / no-load loss). Is obtained as shown in the following equation. The function f ₃ (K, R)
Is set on the basis of experimental data in the factory of the device as in the case of the function f ₂ (K).

Claims (2)

[Claims] 1. A control temperature calculating step of obtaining a control temperature according to a type of the electric device based on a permissible temperature rise specification value of the electric device and ambient conditions, and an infrared ray of the electric device which clearly indicates the control temperature. The image forming step of forming an image for overheat diagnosis by comparing thermal image data with the control temperature and performing a marking process on an infrared thermal image portion of the electric device that has exceeded the control temperature. Equipment overheating diagnostic method. 2. An image conversion step for converting infrared thermal image data in an arbitrary load of an electric device into infrared thermal image data of a rated load, a type of the electric device based on an allowable temperature rise specification value of the electric device and ambient conditions. Management temperature calculation step for determining a management temperature according to the above, and the infrared thermal image of the electric device that exceeds the management temperature by clearly indicating the management temperature and comparing the infrared thermal image data of the electric device with the management temperature An overheat diagnosing method for an electric device, comprising: an image creating step of creating marking image on a portion to create an image for overheat diagnosing.