JPH10227769A - Control system of ultrasonic wave inspecting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control system of an ultrasonic wave inspecting device by which the load and the cost of the ultrasonic wave inspecting device side can be remarkably reduced. SOLUTION: The ultrasonic wave inspecting devices A1 -An respectively comprise a probe 1 and a device body 100, the device bodies 100 are connected through a host computer C and a network bus Nb, and the host computer C has a data memory M. The data on a subject obtained by the ultrasonic wave inspecting devices A1 -An is analyzed and determined by the host computer C, and is stored in the data memory M. The host computer C grasps the diagnosis of the ultrasonic wave inspecting devices A1 -An , and the indications of the deterioration of the probes 1 or the like on the basis of the self-diagnosis program. The data on each probe 1 is stored in the data memory M, and each ultrasonic wave inspecting device A1 -An can read the data through the host computer C.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a management system for an ultrasonic inspection apparatus which stores various data obtained by the ultrasonic inspection apparatus or performs necessary processing based on the data.

[0002]

2. Description of the Related Art Nondestructive inspection apparatuses (ultrasonic inspection apparatuses) using ultrasonic waves are used in many industries from inspection of steel and metals to semiconductor inspection recently. The device is
It is used in many departments, from in-line in-situ inspection to R & D tools. In addition, they have various shapes, ranging from a handy type that can be carried by an inspector to an installation type that is installed at a site or the like. FIG. 10 shows a representative apparatus configuration.

FIG. 10 is a block diagram of an ultrasonic inspection apparatus. The ultrasonic probe 1 (hereinafter, probe) is a sensor unit that transmits and receives ultrasonic waves. Ultrasonic transmission / reception circuit 2 (hereinafter, referred to as
The transmission / reception circuit) is a circuit for transmitting and receiving ultrasonic waves from the probe 1, and usually generates (transmits) ultrasonic waves by exciting a piezoelectric vibrator in the probe 1 with a high-voltage impulse signal. The received small signal is amplified to a predetermined voltage signal level by an amplifier. The waveform processing circuit 3 is a processing unit for displaying an inspection result based on a received waveform. For example, a part of a waveform is extracted by a gate circuit, the maximum value is extracted, and the waveform is compared with a predetermined determination level. A pass / fail is determined, and an ultrasonic image is formed by sequentially displaying the extracted maximum value at a predetermined position on the display unit 4 as a gray value. Control unit 5
Controls the transmission / reception circuit 2 and the waveform processing circuit 3.
Recently, the control unit 5 has a personal computer (hereinafter referred to as P
Examples configured by C) are increasing.

[0004] In addition to the above, an installation-type ultrasonic inspection is provided with a transport device for movement, a scanner for changing the position of a probe or a subject, and the like. In the above description, one probe is used, but two probes are used in the inspection method (two-probe method) in which transmission and reception are performed by different probes. Further, in the case of a large test object (test object) used in a steel line or the like, the number of probes may reach tens to hundreds. In that case, it is common to increase the number of transmitting and receiving circuits in accordance with the number of probes. An array probe in which several tens to several hundreds of micro transducers are arranged in one probe may be used.

[0005]

In the above prior art, the waveform processing circuit 3 analyzes and determines the ultrasonic reception signal using various kinds of signal processing software according to the subject. However, in the case of a large specimen used for steel or the like, the number of probes may reach several hundreds, and in this case, software for analyzing, judging, and storing continuous data of ultrasonic reception signals is enormous. It will be. In addition, the above analysis,
For determination and storage, high-speed and large-capacity computer hardware such as a CPU, a memory, and a storage medium is required, which greatly increases the cost of the entire apparatus. Also, for example, even a relatively small ultrasonic inspection apparatus such as a handy type is provided with means for analyzing and determining ultrasonic reception signals, so that inspection data can be collected. When the information is to be stored and managed, the same problem as described above occurs.

[0006] Further, when a defect occurs in the ultrasonic inspection apparatus, it must be repaired, and for that purpose, it is necessary to have a specialized maintenance person. When notified of the occurrence of a failure, it is desirable that a specialist maintenance person asks for the symptoms of the failure by telephone and narrows down the failure, but such interviews should identify which part of the equipment has the failure. Is often not possible. Therefore, maintenance personnel should first go to the installation location of the equipment, investigate the symptoms of the problem, return to the maintenance base once, arrange replacement parts according to the symptoms, return to the installation location of the equipment again, and perform repairs. Normal. Therefore, the time and cost required for repairs by maintenance personnel are increased.

Further, in order to perform an appropriate test, it is necessary to select and use a probe matching a subject from among many probes. By the way, the probe is easily damaged due to the reason described later, and a new probe is frequently replenished, and its characteristics deteriorate as it is used. For this reason, in order to perform an appropriate inspection, the user needs to frequently inspect the characteristics of not only a new probe but also the probe in use and record the characteristics. However, such inspections and records place a heavy burden on the user. In addition, since the deterioration of the characteristics causes the above-mentioned inconvenience, it is desirable to predict this early, but it is difficult for the user to make such a prediction.

The reason for the damage of the probe described above is as follows. Ultrasonic inspection methods include direct contact method, water immersion method,
There are three methods of local immersion. In the direct contact method, a probe is directly contacted with a subject via a couplant (glycerin, machine oil, or the like), and an inspection is performed while manually or automatically changing the position of the probe on the subject. At this time, the user proceeds while rubbing the probe. In the water immersion method, a subject and a probe are placed in a water tank, and water is used as an ultrasonic wave propagation medium between the two. The local immersion method is a method in which only the space between the two is immersed in water. In both the immersion method and the local immersion method, the probe is constantly in contact with water. Because the working environment of the probe is bad in any of these methods,
Probes often break after a period of use.
Further, when a probe is attached to an automatic scanning mechanism or the like for inspection, there are many sudden accidents such that the sensor collides with an object or the like and is broken. Since the transducer for transmitting and receiving ultrasonic waves in the probe is made of a thin ceramic or the like, it is very susceptible to mechanical vibration and shock. In many cases, the probe was dropped on the floor during the replacement or manual inspection and was broken. For these reasons, probes are treated the same as consumables.

Furthermore, since the probe is hand-made, the quality of the probe varies widely. Even when used under the same conditions, the probe may not break at all, may break immediately, and may be broken in various ways. If the vibrator breaks due to a sudden accident, there is no signal received by the ultrasonic wave. However, if the vibrator part is gradually destroyed (due to separation, etc.) due to the intrusion of water, the ultrasonic wave is gradually received. The signal level decreases (the above-described characteristic deterioration). In the former case, since no signal is received, it is easy to detect that the device operation is abnormal, but in the latter case, the change is gradual, and it is easy to overlook that the probe has an abnormality for a certain period (see above). Difficult to predict).

An object of the present invention is to solve the above-mentioned problems in the prior art and to provide an ultrasonic inspection apparatus management system capable of greatly reducing the burden and cost on the ultrasonic inspection apparatus side.

[0011]

In order to achieve the above-mentioned object, the invention according to claim 1 comprises a probe and an apparatus main body.
One or more ultrasonic inspection apparatuses, a host computer, a transmission line connecting the ultrasonic inspection apparatus and the host computer, and a data storage unit, and the host computer, the ultrasonic inspection apparatus The obtained data is collected via the transmission path, and a management system for an ultrasonic inspection apparatus is configured including a data collection unit for storing the data in the data storage unit.

According to a second aspect of the present invention, in the management system for an ultrasonic inspection apparatus according to the first aspect, the data is test data of the subject and the host computer stores the test data of the subject in the host computer. And a determination means for analyzing and determining

According to a third aspect of the present invention, in the management system for an ultrasonic inspection apparatus according to the first aspect, at least one of the ultrasonic inspection apparatuses is configured to analyze and determine test data of a subject. Wherein the data obtained by the data collecting means of the host computer is data of a result of the determination by the device-side determining means.

According to a fourth aspect of the present invention, in the management system for an ultrasonic inspection apparatus according to the first aspect, the data includes:
First test data obtained when the probe of the specific ultrasonic inspection apparatus is connected to the apparatus main body, and second test data obtained when the probe is separated from the apparatus main body, A command signal output unit for outputting a command signal for obtaining the first test data and the second test data; a command signal output unit for outputting the first test data and the second test data; An abnormal part judging means for judging the presence or absence of an abnormal part of the specific ultrasonic inspection means based on the test data.

According to a sixth aspect of the present invention, in the ultrasonic inspection apparatus management system according to the first aspect, at least one of the ultrasonic inspection apparatuses is provided when the probe is connected to the apparatus main body. An apparatus-side abnormal part determining means for determining the presence or absence of an abnormal part based on the first test data obtained and the second test data obtained when the probe is separated from the apparatus main body, and The data collected by the data collection unit of the host computer is data of a result of determination by the device-side abnormality location determination unit.

According to an eighth aspect of the present invention, in the ultrasonic inspection apparatus management system according to the first aspect, the data is reception level data, and the host computer stores the reception level data. And a reception level comparison unit that compares an average value of a plurality of previous continuous data including the latest data or the latest data with a predetermined reception level setting value. I do.

According to a ninth aspect of the present invention, in the management system for an ultrasonic inspection apparatus according to the first aspect, the data is data of a reception level, and the host computer stores the data of the reception level in the host computer. It is characterized in that a change amount comparing means for comparing a difference or a change rate between the latest data and the immediately preceding data with a predetermined change amount set value is provided.

According to a tenth aspect of the present invention, in the ultrasonic inspection apparatus management system according to the first aspect, the data is data of a reception level, and the host computer stores the data of the reception level in the host computer. Receiving level comparing means for comparing the latest data among them or the average value of a plurality of previous continuous data including the latest data with a predetermined receiving level setting value; When the latest data or the average value is determined to be larger than the reception level setting value, a change comparison that compares a difference or a change rate between the latest data and the immediately preceding data with a predetermined change setting value. Means.

According to an eleventh aspect of the present invention, in the management system for an ultrasonic inspection apparatus according to the first aspect, at least one of the ultrasonic inspection apparatuses includes the latest data of the reception level data or the latest data. The apparatus further includes a device-side reception level comparison unit that compares an average value of a plurality of previous consecutive data including the latest data with a predetermined reception level set value, and includes the data collection unit of the host computer. The data to be collected is data obtained as a result of comparison by the device-side reception level comparing means.

According to a twelfth aspect of the present invention, in the ultrasonic inspection apparatus management system according to the first aspect, at least one of the ultrasonic inspection apparatuses includes the latest data of the reception level and the immediately preceding data. A device-side change comparing means for comparing a difference or a change rate with data with a predetermined change set value; and wherein the data collected by the data collecting means of the host computer is the device-side change. The data is a result of comparison by the minute comparing means.

According to a thirteenth aspect of the present invention, in the ultrasonic inspection apparatus management system according to the first aspect, at least one of the ultrasonic inspection apparatuses includes the latest data among the reception level data or the latest data. An apparatus-side reception level comparing means for comparing an average value of a plurality of previous consecutive data including the latest data with a predetermined reception level setting value; and Or, when it is determined that the average value is larger than the reception level set value, a device-side change comparison means for comparing a difference or change rate between the latest data and the immediately preceding data with a predetermined change set value. Wherein the data collected by the data collection unit of the host computer is the device-side reception level comparison unit and the device-side variation comparison unit. Characterized in that the data is the result of the comparison by.

According to a fourteenth aspect of the present invention, in the ultrasonic inspection apparatus management system according to the first aspect, the data is data of the probe of a specific ultrasonic inspection apparatus,
Further, the host computer is provided with probe data receiving means for receiving the data of the probe.

According to a fifteenth aspect of the present invention, in the management system for an ultrasonic inspection apparatus according to the first aspect, the data is predetermined data in each component constituting the apparatus main body. On the host computer,
It is characterized by comprising a component data receiving means for receiving predetermined data of the component.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the illustrated embodiments. FIG. 1 is a block diagram of a management system for an ultrasonic inspection apparatus according to an embodiment of the present invention. In this figure, A _1, ............ A _n represents a number of ultrasonic examination apparatus in a different position. Each of these ultrasonic inspection apparatuses includes an apparatus main body 100 and a probe 1 connected thereto. The apparatus main body 100 will be described later with reference to FIG. C is a host computer, and M is a data storage unit in which various data are written and read by the host computer C. N _B is the network bus, constitutes a transmission line for communicating the device main body 100 of the ultrasonic inspection apparatus A ₁ to A _n and the host computer C. Network bus N _B is, if small scale L
This is an AN, and in the case of a large scale, there is, for example, the Internet using a telephone line or the like. That is, each ultrasonic inspection apparatus A ₁
To A _n has a LAN suitable as long as it is present in the plant, and Internet suitable in the case where each of the ultrasonic inspection apparatus A ₁ to A _n are scattered to a remote location.

FIG. 2 is a block diagram showing the configuration of the apparatus main body 100 shown in FIG. In this figure, the same or equivalent parts as those shown in FIG. 6 interface interposed between the control unit 5 and the Ne network bus N _B, 7 denotes a switch element provided between the probe 1 and the ultrasonic wave transmission and reception circuit 2. L ₁ is a signal communication line for controlling the opening and closing of the switch element 7 by the control unit 5, L ₂ is a signal communication line for transmitting an output signal of the ultrasonic transmission / reception circuit 2 to the control unit 5, L ₃ is a waveform processing circuit 3 signal connecting line for transmitting the output signal to the control unit 5, L ₄ the control unit 5
And signal contact lines for sending and receiving signals between the interface 6, L ₅ is the interface 6 and the network bus N
_This is a signal connection line connecting _B. The operation program of the control unit 5 according to the present embodiment includes a program necessary for exchanging data with the host computer C in addition to the operation program of the conventional control unit 5.

Next, the operation of this embodiment will be described. In the present embodiment, the multiple ultrasonic inspection devices A _{1 to} A
_n, the network bus N _B, the host computer C, and using the network consisting of the data storage unit M, by the host computer C (1) each of the ultrasonic inspection apparatus A ₁ ~
Processing of the data A _n is taken, (2) failure diagnosis of each of the ultrasonic inspection apparatus A ₁ to A _n, (3) a probe management, diagnostic,
And (4) management and diagnosis of each component constituting the apparatus main body. This will be described below in order.

[0027] (1) Conventional treatment of the ultrasonic inspection apparatus A ₁ data to A _n is collected, the ultrasonic inspection apparatus analyzes ultrasonography, determination, was processing the data stored in the apparatus main body. However, in the present embodiment, all or some of them are
Do with. In the former case, that is, analysis, determination,
When all data storage is performed by the host computer C, the control unit 5 of the ultrasonic inspection apparatus
Call host computer C via the network bus N _B, after requesting the processing of data, when implementing the ultrasound to the subject, the output signal or the output signal of the waveform processing circuit 3 of the ultrasonic wave transmission and reception circuit 2 interface 6 from the control unit 5, is collected via a network bus N _B to the host computer C. The host computer C temporarily stores the collected data in the data storage unit M, and performs analysis and determination based on the data. For example, by analyzing an ultrasonic train collected from an ultrasonic inspection apparatus that has received a processing request, the presence or absence of an internal defect of the subject inspected by the ultrasonic inspection apparatus, or when an internal defect is found When the type of the defect is determined, for example, the presence of internal cavities, cracks, inclusions, and when a large number of the same subject are inspected,
Calculation of a defect rate (for example, when inspecting the joint surface of the subject, what percentage of the subject has a peel defect on the joint surface) is calculated. Further, processing such as setting a threshold value for determining the quality of the subject based on the data is performed. On the other hand, when part of the analysis, determination, and data storage of the ultrasonic inspection is performed by the host computer C, for example, when the analysis and determination functions are provided on the apparatus main body 100 side,
The analysis and determination are performed by the apparatus main body 100, and the results are sent to the host computer C, which then stores the results in the data storage unit M.
To save. In particular, this method is effective when the load of analysis and determination of the ultrasonic inspection apparatus is small, such as when the number of subjects to be examined at one time is small. However, it goes without saying that the analysis and determination may be performed by the host computer C even if the function of analysis and determination is provided in the apparatus main body 100.

As described above, in the present embodiment, the data obtained by the ultrasonic inspection apparatus is collected by the host computer C, and the analysis and the judgment are performed based on the data. CPU and memory of the control unit 5 of
The storage medium and the like can be simplified, and the cost of the ultrasonic inspection apparatus can be reduced. Further, the control software is often changed or revised. In this case, however, only the software of the host computer C needs to be changed or revised, and no change or revision is required in each ultrasonic inspection apparatus. Therefore, the manpower and time required for the change and revision can be significantly reduced. Furthermore, since the data, the determination result, and the like are stored in the data storage unit M, the labor, time, and cost required for managing the data and the like on the user side of the ultrasonic inspection apparatus can be eliminated. Further, even when the data of the result of analysis and determination obtained on the apparatus main body 100 side is stored in the data storage unit M via the host computer C, as described above, the data on the user side of the ultrasonic inspection apparatus may be stored. It is possible to eliminate the labor, time, and cost required for management of the above.

[0029] (2) As the failure diagnosis described above for each ultrasonic inspection apparatus A ₁ to A _n, when a problem occurs in the ultrasonic inspection apparatus, maintenance personnel diagnosis in person to the installation location of the ultrasonic inspection device In this embodiment, this is performed by the host computer C. Therefore, the host computer C
Has a self-diagnosis program. The self-diagnosis operation of the host computer C will be described with reference to the flowcharts shown in FIGS.

The host computer C waits for a request for a self-diagnosis (procedure S ₁ shown in FIG. 3). If a self-diagnosis is required in any of the ultrasonic inspection apparatuses, such as when a periodical diagnosis has expired or a failure has occurred in the apparatus, the user of the ultrasonic inspection apparatus will be notified of the apparatus main body 100 Select "Self-diagnosis" from the menu displayed in.
This selection controller 5, the interface 6, is transmitted over the network bus N _B to the host computer C,
As a result, the host computer C starts a diagnostic operation. First, an instruction to move the probe of the ultrasonic inspection apparatus to the inspection (test) position is issued (step S ₂ ), and the end of the movement is waited for (step S ₃ ). In response to this instruction, the control unit 5 operates the drive mechanism of the probe 1 to move the probe 1 to a predetermined position. This position is, for example, in a device in which a test object is placed in a water tank and inspected, the surface of the flat part of the water tank is regarded as the test object, and is located at a predetermined distance from the surface. When the movement of the probe 1 is completed, the control unit 5 transmits this to the host computer C.

When confirming the completion of the movement, the host computer C instructs the switch element 7 to be turned on (procedure S ₄ ) and turns on.
(Step S ₅ ), and instructs transmission / reception of the test signal for the test and collection of data by the transmission / reception (Step S ₆ ), and waits for completion of the collection (Step S ₇ ). The control unit 5 transmits a signal to the ultrasonic transmission / reception circuit 2 with the switch element 7 closed, and the ultrasonic transmission / reception circuit 2 generates an ultrasonic wave from the probe 1 and receives a reflected wave from the flat part of the water tank, A signal corresponding to this is output. The waveform processing circuit 3 processes a signal from the ultrasonic transmission / reception circuit 2 and outputs a signal corresponding to the signal. The control unit 5 collects signals output from the ultrasonic transmission / reception circuit 2 and the waveform processing circuit 3 via the signal communication lines L ₂ and L _3, and transmits the signals to the host computer C when the collection is completed.

When the host computer C receives the report of the completion of collection, the host computer C instructs the control unit 5 to turn off the switch element 7.
(Procedure S ₈ ), and waits for the end of OFF (procedure S ₈ ).
₉ ). The switch 7 O control unit 5 a signal contact lines L ₁
When you FF sends it to the host computer C, the host computer C instructs transmission and reception of test signals for testing, and the collection of data by the transmission and reception again (Step S _10), waits for the end of sampling (steps S _11). The control unit 5 transmits a signal to the ultrasonic transmission / reception circuit 2 with the switch element 7 turned off. In this case, the switching element 7 is O
Since the probe 1 is not connected in the FF state, the transmission pulse itself to the ultrasonic transmission / reception circuit 2 is used as a reception signal. However, instead of such means, a reference signal generating circuit may be separately provided, and this output signal may be used as a reception signal. In this state, the control unit 5 collects signals output from the ultrasonic transmission / reception circuit 2 and the waveform processing circuit 3 via the signal communication lines L ₂ and L _3, and transmits the signals to the host computer C when the collection is completed. . When the host computer C receives a report of the data collection termination instructs the transfer of the data collected (Step S _12), waits for transfer of data (Step S _13). The host computer C When the transmission is finished the data from the control unit 5 stores stores the transmitted data in the data storage unit M (Step S _14).

Next, the host computer C makes a diagnosis based on the collected data. First, the output data of the ultrasonic transmission / reception circuit 2 when the switch element 7 is connected (when the probe 1 is connected) is extracted from the data storage unit M, and it is determined whether or not the data is normal (FIG. Step S ₁₅ shown in 4). This determination is made by comparison with a known output signal of the ultrasonic transmission / reception circuit 2 when receiving the ultrasonic reflected wave from the flat part of the water tank. If it is normal, this time when the switch element 7 is in the ON state from the data storage unit M (when the probe 1 is connected)
Take the output data of the waveform processing circuit 3, the data is to determine whether normal or not (Step S _16). This determination is made by comparison with a known normal waveform circuit output signal. If successful, the control unit 5, "no abnormality" on the display unit 4 instructs to display the fact (Step S _17). Further, if it is determined to be abnormal in Step S _16, "waveform processing circuit 3 is abnormal" instructs to display the effect that the control unit 5 (Step S _18).

[0034] When the host computer C is determined to be abnormal in the process at steps S _15, taken out ultrasound output data transmission and reception circuit 2 when the OFF the switching element 7 from the data storage unit M, the data is normal It determines whether there (Step S _19). This judgment is made by the ultrasonic transmission / reception circuit 2
Is compared with a known output signal output from the ultrasonic transmission / reception circuit 2 when a transmission pulse is received. If normal, the control unit 5 displays "Probe 1" on the display unit 4.
Instructs to display a message indicating an abnormality "(Step S _20). Further, if it is determined to be abnormal in Step S _19, "ultrasonic wave transmission and reception circuit 2 abnormality" instructs to display the effect that the control unit 5 (Step S _21). Thereby, the diagnosis of each part of the ultrasonic inspection apparatus which has requested the diagnosis is performed.

In FIG. 2 and the description of the above operation,
Selection of the "self" has been described an example of performing the ultrasonic inspection apparatus A ₁ to A _n-side, it is also possible to command the "self" from the host computer C side. In the above description, the switch element 7 is provided, and the probe 1 is
Has been described as an example in which the connection state is selectively set to the connection state or the non-connection state. However, the switch element 7 is not always necessary, and the user may mount the probe 1 on the apparatus main body 100 or remove the probe 1 from the apparatus main body 100. Good. In this case, instead of the host computer C instructs the steps S _4, the control unit 5 performs an instruction to display to mounting the probe 1 on the display unit 4, and, instead of the instructions in Step S ₈ Thus, an instruction to display on the display unit 4 to remove the probe 1 is issued. Furthermore, in the above description of the operation, an example in which the failure diagnosis program is provided in the host computer C has been described. The data may be transmitted to the host computer C and stored in the data storage unit M.

As described above, in the present embodiment, the ultrasonic transmission / reception circuit 2 for transmitting / receiving ultrasonic waves by the probe 1
And the output signal of the waveform processing circuit 3 and the output signal of the ultrasonic transmission / reception circuit 2 and the output signal of the waveform processing circuit 3 when the probe 1 is not involved are collected by the host computer C, respectively.
Since the diagnosis of the ultrasonic inspection apparatus is performed based on these, it is possible for the maintenance staff to judge the failure point without going to the installation point of the ultrasonic inspection apparatus, thereby
Not only can the time required to recover the failed ultrasonic inspection device be significantly reduced, but also the labor and time required for maintenance personnel can be reduced, and the user can simply request a diagnosis. Therefore, various troubles associated with the diagnosis can be omitted. In addition, since the diagnosis is performed automatically and requires little trouble, the diagnosis can be performed frequently, and by executing the diagnosis, the reliability of the apparatus and, consequently, the reliability of the test result can be improved. it can. Further, the history of failures of the ultrasonic inspection apparatus can be reliably stored.

Further, the failure diagnosis program is stored in the main unit 1 of the apparatus.
Even when a means for sending only the data of the diagnosis result to the host computer C and storing it in the data storage unit M is adopted, since there is a failure point on the device body 100 side, this is immediately sent to maintenance personnel. As a result, it is possible to save time and effort for maintenance personnel as described above, to shorten the time required for recovery from the failure, and to reduce
Since there is no need to save the failure history on the side, the capacity of the storage unit of the apparatus can be reduced, and the failure history can be reliably stored.

(3) Probe Management and Diagnosis As described above, probes are replenished frequently and newly.
Since the characteristics deteriorate with use, it is desirable for the user to grasp the characteristics of all probes. Here, various data of the probe will be described. FIG. 5 is a diagram illustrating an example of probe data. When the probe is shipped, the data is written in the column A shown in FIG. 5 by the manufacturer. There are a nominal value column and an actual measurement value column, and the nominal value column includes the model, serial number, and other specifications necessary for ordering the probe, such as the transducer diameter, center frequency, focal length, etc. There are items. In the example shown in FIG. 5, the beam diameter is described in addition to the above. In the actual measurement value column, data group of shipping inspection is recorded, and in it, items such as date, inspector, center frequency, upper limit frequency, lower limit frequency, bandwidth, focal length, sensitivity, capacitance, etc. There is. In addition, a pulse width and a beam diameter which are indexes of the resolution of the probe are described.

After shipment of the probe, the inspection of the probe is performed as necessary or periodically by the inspector, or each time the above-described self-diagnosis is performed, and the column of the measured values of the data increases each time. In the example shown in FIG. 5, two inspections are performed, and the results of each inspection are written in the B and C columns. In this test example, a re-test is performed for “pulse width” and “sensitivity”, and it can be seen from the change in the numbers that the probe is gradually damaged. In addition,
In the illustrated example, the inspection of the “pulse width” and the “sensitivity” is performed by the inspector. However, during the self-diagnosis described in the above (2), the program for the measurement is automatically inserted. Obviously, various measurements are possible.

In the present embodiment, each ultrasonic inspection apparatus A ₁
For each probe each user of to A _n's to store the characteristic data as shown in FIG. 5 in the data storage unit M. That is, when each user owns a new probe, the user transmits the characteristic data to the host computer C.
And the host computer C stores it in the data storage unit M. Then, every time the probe is inspected, the measured values are added to the stored data and stored as shown in columns B and C in FIG. In addition,
The data of these probes is stored in a spreadsheet format (format) used by the PC software.
When the user requires a characteristic data of the probe via the network bus N _B requests data transmission of the probe to the host computer C, the host computer C data storage unit the data of the probe in accordance with this read from M, which via a network bus N _B, and transmits to the ultrasonic inspection device for which the request.

As described above, in the present embodiment, the characteristic data of the probe held by each of the ultrasonic inspection apparatuses A _{1 to An} is stored in the data storage unit M, so that the latest data of the probe is obtained. The best probe for testing the subject can be selected in a short time,
Inspection efficiency can be improved.

Further, this embodiment has a function of judging whether the probe is normal or abnormal, and grasping a sign of deterioration of the probe. This function will be described with reference to a reception level characteristic diagram shown in FIG. 6 and a flowchart shown in FIG. In FIG. 6, the horizontal axis indicates the number of inspections, and the vertical axis indicates the reception level. The determination of whether the probe is normal or abnormal is usually made by setting a threshold value for the reception level and comparing the actual reception level with the threshold value. The value V _S shown in FIG. 6 indicates the above threshold value. The value ΔV shown in the figure indicates a deviation between the previous reception level and the current reception level,
A threshold value ΔV _S is provided for the reception level deviation. In FIG. 6, the reception level is kept almost constant up to the number of inspections (N-1), but the reception level rapidly decreases after the number of inspections N, and reaches the threshold ΔV until (N + n) times. The characteristics of probes that are below _S are shown. In the present embodiment, the normality / abnormality of the probe and the sign of deterioration are grasped using the threshold values V _S and ΔV _S.

Next, the operation of the host computer C for diagnosing the failure of the probe and grasping the signs of deterioration will be described with reference to the flowchart shown in FIG. In the present embodiment, threshold values V _S and ΔV _S are set in advance (procedure S ₃₁ shown in FIG. 7). If, for example, a probe check instruction is set in the failure diagnosis program of the above (2), the system waits for the instruction, or waits for a probe check request from the inspector (step _S32 ). Upon receiving this instruction or request, the host computer C reads the reception level (output value of the ultrasonic transmission / reception circuit when the switch element 7 is ON) V _B1 and the current reception level V _B0 in the previous inspection (Step S). ₃₃ ) First, the current reception level V _B0 is compared with the threshold value V _S (step _S34 ). When the check is performed at the request of the inspector, the value V _B1 is the value two times before and the value V _B0 is the previous value.

[0044] In the process of the procedure S _34, the current reception level V _B0
Is greater than or equal to the threshold V _S , then the previous reception level V
The absolute value of the difference between _B1 and the current reception level V _B0 is the threshold Δ
It is determined whether or not V _{S is} larger than V _S (step _S35 ). If the absolute value of the difference is equal to or smaller than the threshold value ΔV _S , an indication of “probe normal” is issued (step S ₃₆ ), and if the absolute value of the difference exceeds the threshold value ΔV _S , A display meaning "warning" is instructed (step _S37 ). That is, the current reception level V _B0 is equal to or higher than the threshold value V _S , and may be used. However, since the current reception level is lower than the previous reception level by the threshold ΔV _S or more, A warning is given as a sign of probe deterioration. If it is determined in step _S34 that the current reception level V _B0 is less than the threshold value V _S , this probe is obviously abnormal, and an instruction to indicate “probe abnormal” is issued (step _S38 ).

As described above, in the present embodiment, the threshold values V _S and ΔV _S are set, and the current reception level V _B0 and the threshold value V _S , and the previous reception level V _B1 and the current reception level V _B1 are set. Since the absolute value of the difference from V _B0 is compared with the threshold value ΔV _S , it is possible to know not only whether the probe is normal or abnormal, but also a sign of deterioration. If the signs of deterioration can be known in this way, replacement probes can be purchased or measures can be taken such as shortening the interval of self-diagnosis and taking precautions. Even when it becomes unusable, it is possible to respond quickly.

It should be noted that in the description of the above embodiment,
The example in which the determination of the abnormality and the warning (sign) is performed using the present reception level V _B0 and the previous reception level V _B1 has been described. It is also possible to determine an abnormality or to compare the rate of change (differential value) of the current reception level with respect to the previous reception level with a threshold value to determine a sign. Further, in the above-described embodiment, an example in which both the determination of the presence or absence of the abnormality and the determination of the sign are described, however, both may be performed separately. Further, it is clear that the sign grasping means can be applied to components (ultrasonic transmitting / receiving circuit, waveform processing circuit) other than the probe. Further, in the description of the above embodiment, an example is described in which a program for determining whether the probe is normal, abnormal, or a sign of failure is provided in the host computer C.
The control unit 5 may determine whether the probe is normal, abnormal, or a sign of failure on the device body 100 side, and send only the determination result to the host computer C and store it in the data storage unit M. This eliminates the need for the storage unit for storing the data of the probe diagnosis results on the apparatus main body 100 side.

(4) Management and Diagnosis of Each Component Constituting the Apparatus Main Body In the above (3), management and diagnosis of the probe have been described. In this embodiment, in addition to probe management and diagnosis,
It also manages and diagnoses each component constituting the apparatus main body 100, for example, each component of the ultrasonic transmission / reception circuit 2, each component of the waveform processing circuit 3, and the like. This will be described with reference to FIGS. 8 and 9 exemplifying a transmission pulse circuit in the ultrasonic transmission / reception circuit 2. FIG. 8 is a diagram showing a transmission pulse voltage. In this figure, the horizontal axis represents time, and the vertical axis represents voltage. The transmission pulse circuit is a circuit for transmitting an ultrasonic wave by giving the impulse signal shown in FIG. In order to transmit a normal ultrasonic wave, the magnitude V of the transmission pulse voltage output from the transmission pulse circuit and the pulse fall time T (both are shown in FIG. 8) are output as set values. There must be. As in the case of the probe 1 described above, it is desirable for the user to grasp the characteristics of the transmission pulse circuit. Here, various data in the transmission pulse circuit will be described with reference to FIG.

FIG. 9 is a diagram showing an example of data of the transmission pulse circuit. At the time of shipment of the ultrasonic inspection apparatus, the data is written in column A shown in FIG. 9 by the manufacturer. There are a nominal value column and an actual measurement value column, and the nominal value column includes items such as a model, a serial number, a maximum pulse voltage, and a pulse fall time. In the actual measurement value column, the inspection content, date, inspector,
Set pulse voltage (In the figure, set voltage 50, 100, 15
0, 200, 250, and 300 V are shown), output pulse voltage, pulse fall time, and the like.

As in the case of the probe, after shipment of the ultrasonic inspection apparatus, the inspection of the transmission pulse circuit is performed by the inspector as necessary or periodically, or each time the above-described self-diagnosis is performed, and each time. The column of measured data values increases.
When self-diagnosis is used, the switch element 7 is turned off.
The impulse signal at that time becomes a received signal as it is, and is received by the signal communication line L _{2. The} host computer C captures the received signal and stores it in the data storage unit M. In the example shown in FIG. 9, two inspections are performed,
The results of each round are written in columns B and C,
From the change in the number, whether the transmission pulse circuit is normal or abnormal is determined. When the user requires data of the transmitted pulse circuit, it requested viewing data transmission of the transmission pulse circuit to the host computer C via the network bus N _B,
The host computer C accordingly reads the data of the transmission pulse circuit from the data storage unit M, which via a network bus N _B, and transmits to the ultrasonic inspection device for which the request. In the illustrated example, the inspection is performed by the inspector. However, during the self-diagnosis described in the above (2), automatic measurement is possible by inserting a program for the measurement. it is obvious. In addition, it is clear that predetermined data in the device main body components other than the transmission pulse circuit can be managed and diagnosed in the same manner as in the case of the transmission pulse circuit.

As described above, in the present embodiment, the predetermined data of the components of the apparatus main body in each of the ultrasonic inspection apparatuses A _{1 to An} is stored in the data storage unit M. Can manage and diagnose.

The above, in this embodiment (1) the processing of data by each ultrasonic inspection apparatus A ₁ to A _n are collected, (2)
Failure diagnosis of each of the ultrasonic inspection apparatus A ₁ to A _n, (3) a probe management, diagnostics, (4) Administration of each component constituting the apparatus main body has been described diagnostic primarily installed type these explanations It is an explanation of the ultrasonic inspection device of the above. However, the present embodiment, installation type not limited to the ultrasonic inspection apparatus, an interface 6 shown in FIG. 2 in a conventional portable ultrasound device, the switching element 7, the signal contact lines L ₁ ~L By adding ₅ , it is possible to perform the functions (1) to (3) just as in the case of the stationary ultrasonic inspection apparatus. In this case, the portable ultrasonic inspection apparatus may connect the network bus and the interface only when necessary. Further, in the description of the present embodiment, a case where a large number of ultrasonic inspection apparatuses exist has been described as an example, but it is needless to say that this can be applied even if there is one ultrasonic inspection apparatus. is there.

[0052]

As described above, according to the present invention, the ultrasonic inspection apparatus is connected to the host computer via the transmission line, and the data storage unit is connected to the host computer, so that the ultrasonic inspection apparatus can obtain the data. The collected data is collected by the host computer and stored in the data storage unit.Based on the stored data, analysis of the test data of the subject, determination and storage of the results, and determination of the presence or absence of abnormalities at specific locations Judgment and saving of results, grasp of signs of probe deterioration,
Or management of each probe, or management of components of the device body,
Since the diagnosis is performed, there is an effect that the burden and cost on the ultrasonic inspection apparatus side can be significantly reduced as follows.

(1) By analyzing and judging the test data of the subject, the mechanism such as the control unit of each ultrasonic inspection apparatus can be simplified, and the cost of the ultrasonic inspection apparatus can be reduced. The labor and time required for the change and revision in the above can be greatly reduced, and the labor, time and cost required for managing data and the like on the ultrasonic inspection apparatus side can be eliminated. Further, even when only the data of the result of analysis and determination is sent to the host computer, the labor, time, and cost required for management of data and the like on the ultrasonic inspection apparatus side can be eliminated. (2) The host computer determines whether or not there is an abnormality in the specific location, so that the maintenance personnel can determine the failure location without going to the installation location of the ultrasonic inspection apparatus, and the ultrasonic inspection that has become defective It is possible to greatly reduce the time required for restoration of the apparatus, reduce the labor and time of maintenance personnel, and save various troubles associated with the diagnosis on the user side. Further, the diagnosis can be frequently performed, and by executing the diagnosis, the reliability of the apparatus and, moreover, the reliability of the test result can be improved. Further, even when only the data of the result of the failure determination is sent to the host computer, the labor and time required for maintenance personnel can be reduced, and the time required for recovery from the failure can be greatly reduced. (3) The host computer or the apparatus main body grasps the signs of the deterioration of the probe, and if there is a sign of the deterioration, purchase a replacement probe or shorten the interval of the self-diagnosis and take measures such as caution. Even when the probe is deteriorated and the probe becomes unusable, it is possible to quickly respond to this. In addition, by managing each probe with the host computer, the latest data of the probe can be obtained, and the optimal probe for the test of the subject can be selected in a short time, thereby improving the test efficiency. Can be done. Furthermore, since the predetermined data of each component of the apparatus main body is managed by the host computer, the management is easy, and diagnosis such as deterioration of the function of the component can be easily performed.

[Brief description of the drawings]

FIG. 1 is a block diagram of a management system for an ultrasonic inspection apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram of the apparatus main body shown in FIG.

FIG. 3 is a flowchart illustrating an operation of a host computer.

FIG. 4 is a flowchart illustrating an operation of the host computer.

FIG. 5 is a diagram showing an example of probe data.

FIG. 6 is a waveform diagram of a reception level.

FIG. 7 is a flowchart illustrating an operation of the host computer.

FIG. 8 is a diagram illustrating a transmission pulse voltage.

FIG. 9 is a diagram illustrating an example of data of a transmission pulse circuit.

FIG. 10 is a block diagram of a conventional ultrasonic inspection apparatus.

[Explanation of symbols]

1 the probe 100 apparatus main body A ₁ to A _n ultrasonic inspection apparatus N _B network bus C host computer M data storage unit

Claims (15)

[Claims] 1. An ultrasonic inspection apparatus comprising a probe and an apparatus main body, at least one ultrasonic inspection apparatus, a host computer, a transmission line connecting the ultrasonic inspection apparatus and the host computer, and a data storage unit. A management system for an ultrasonic inspection apparatus, characterized in that the host computer includes a data collection unit that collects data obtained by the ultrasonic inspection apparatus via the transmission line and stores the data in the data storage unit. 2. The management system for an ultrasonic inspection apparatus according to claim 1, wherein the data is test data of a subject, and the host computer analyzes and judges the test data of the subject. A management system for an ultrasonic inspection apparatus, comprising: a determination unit. 3. The management system for an ultrasonic inspection apparatus according to claim 1, wherein at least one of the ultrasonic inspection apparatuses includes an apparatus-side determination unit that analyzes and determines test data of a subject, and Wherein the data collected by the data collection unit of the host computer is data of a determination result of the device-side determination unit. 4. The management system for an ultrasonic inspection apparatus according to claim 1, wherein the data is first test data obtained when the probe of a specific ultrasonic inspection apparatus is connected to the apparatus main body. And second test data obtained when the probe is separated from the main body of the apparatus, and the host computer has a first test data and a second test data for obtaining the second test data. Command signal output means for outputting a command signal; and abnormal location determination means for determining the presence or absence of an abnormal location of the specific ultrasonic inspection means based on the first test data and the second test data. A management system for an ultrasonic inspection apparatus, comprising: 5. The ultrasonic inspection apparatus management system according to claim 4, wherein connection and disconnection between the probe and the apparatus main body are performed by a switch element that is opened and closed according to an instruction from the host computer. 6. The ultrasonic inspection apparatus management system according to claim 1, wherein at least one of the ultrasonic inspection apparatuses has first test data obtained when the probe is connected to the apparatus main body. And a device-side abnormal portion determining means for determining the presence or absence of an abnormal portion based on second test data obtained when the probe is separated from the device main body, and the data collecting means of the host computer The data collected by
A management system for an ultrasonic inspection apparatus, wherein the management data is data of a determination result of the apparatus-side abnormal portion determination means. 7. The ultrasonic inspection apparatus management system according to claim 6, wherein connection and disconnection between the probe and the apparatus main body are performed by opening and closing a switch element. 8. The management system for an ultrasonic inspection apparatus according to claim 1, wherein the data is data of a reception level, and the host computer provides the latest data or the latest data of the data of the reception level. Management of an ultrasonic inspection apparatus, comprising: a reception level comparison unit that compares an average value of a plurality of previous consecutive data including the latest data with a predetermined reception level setting value. system. 9. The management system for an ultrasonic inspection apparatus according to claim 1, wherein the data is reception level data, and the host computer stores the latest data among the reception level data and the latest data. A management system for an ultrasonic inspection apparatus, comprising: a change amount comparing unit that compares a difference or a change rate with immediately preceding data with a predetermined change amount set value. 10. The management system for an ultrasonic inspection apparatus according to claim 1, wherein the data is data of a reception level, and the host computer provides the latest data or the latest data of the data of the reception level. Average of multiple previous data, including the latest data,
A reception level comparison unit that compares a predetermined reception level setting value with the latest data when the reception level comparison unit determines that the latest data or the average value is larger than the reception level setting value. A management system for an ultrasonic inspection apparatus, comprising: a change amount comparing means for comparing a difference or a change rate with immediately preceding data with a predetermined change amount set value. 11. The management system for an ultrasonic inspection apparatus according to claim 1, wherein at least one of the ultrasonic inspection apparatuses is provided.
First, the device-side reception level comparing the latest reception data among the reception level data or the average value of a plurality of previous consecutive data including the latest data with a predetermined reception level setting value. A management system for an ultrasonic inspection apparatus, comprising: a comparison unit, wherein the data collected by the data collection unit of the host computer is data obtained as a result of comparison by the device-side reception level comparison unit. . 12. The ultrasonic inspection apparatus management system according to claim 1, wherein at least one of the ultrasonic inspection apparatuses is provided.
One of them includes a device-side change comparing means for comparing a difference or a change rate between the latest data of the reception level and the data immediately before the received data with a predetermined change set value, and The management system for an ultrasonic inspection apparatus, wherein the data collected by the data collection unit is data of a result of comparison by the device-side change comparison unit. 13. The ultrasonic inspection apparatus management system according to claim 1, wherein at least one of the ultrasonic inspection apparatuses is provided.
First, the device-side reception level comparing the latest reception data among the reception level data or the average value of a plurality of previous consecutive data including the latest data with a predetermined reception level setting value. Comparing means, when the device-side reception level comparison means determines that the latest data or the average value is larger than the reception level set value, determines the difference or change rate between the latest data and the immediately preceding data in advance. A device-side change comparing means for comparing the data with a predetermined change set value, and wherein the data collected by the data collecting means of the host computer is the data received by the device-side reception level comparing means and the device-side change. A management system for an ultrasonic inspection apparatus, which is data of a result of comparison by minute comparing means. 14. The management system for an ultrasonic inspection apparatus according to claim 1, wherein the data is data of the probe of a specific ultrasonic inspection apparatus, and the host computer receives the data of the probe. A management system for an ultrasonic inspection apparatus, comprising: 15. The management system for an ultrasonic inspection apparatus according to claim 1, wherein said data is predetermined data in each of constituent units constituting said apparatus main body, and said host computer has said configuration. A management system for an ultrasonic inspection apparatus, comprising: a component data receiving unit that receives predetermined data of a unit.