WO2010055574A1

WO2010055574A1 - Cable inspection method, cable inspection d device, jig device inspection method, and computer-readable recording medium

Info

Publication number: WO2010055574A1
Application number: PCT/JP2008/070745
Authority: WO
Inventors: スンイルホング; ヨングチャンイ; サンググォンイ; ヨングミンイ; ギョウォンチェ; ヒョナムイム
Original assignee: 東京エレクトロン株式会社
Priority date: 2008-11-14
Filing date: 2008-11-14
Publication date: 2010-05-20

Abstract

A cable inspection method comprises a step for storing reference information that is a reference for judging a connection state of a cable in a reference information storage unit, a step for selecting a cable to be inspected, a step for searching for the reference information corresponding to the selected cable from the reference information storage unit, a step for inspecting the connection state of each pin of a first connector and a second connector that are connected to both ends of the cable, and a step for displaying connection error information with respect to each pin of the first and second connectors of the cable according to the inspection result.

Description

Cable inspection method, cable inspection apparatus, jig apparatus inspection method, and computer-readable recording medium

The present invention relates to a cable inspection method, a cable inspection device, an inspection method for a jig device to which a cable is connected, and a computer-readable recording medium on which a program for executing the cable inspection method is recorded. The present invention relates to a cable inspection method and a cable inspection apparatus for inspecting a connection state of each pin of a first connector and a second connector coupled to each other to inspect a disconnection, short circuit or connection of a cable.

Generally, automated process equipment including various equipment such as semiconductor equipment is controlled by a computer, and for this purpose, a cable is used as a means for transmitting a signal between the equipment and the computer.

However, depending on the type of signal used in the equipment, that is, DC, AC, analog, digital, etc., the type and function of the cable differ, and the thickness and shape of the cable differ. Different connectors are used.

Since such a cable is composed of many lines of signal lines and is formed in one harness shape, if an abnormality such as disconnection, short circuit, or connection occurs, the presence or absence of the abnormality is confirmed. It was not easy to distinguish between inspection and abnormal signal lines.

Conventionally, in order to inspect the presence or absence of such a cable abnormality, a probe connected to the tester or the like is inspected by using a tester or a digital voltmeter (DVM). The presence or absence of an abnormality in the cable was inspected by detecting the amount of signal by contacting both ends of the corresponding signal line of the cable to be tried.

However, according to the conventional cable inspection method, there is a problem that the inspection time becomes long because an abnormality such as disconnection, short circuit or connection is inspected by connecting individual pins of each connector.

In addition, when the number of signal lines included in the cable is large, it is not easy to distinguish the signal lines, so that the inspection work is not easy, and an accurate inspection is not performed. There is.

In order to solve the above-described problems of the prior art, an object of the present invention is to provide a cable inspection device and an inspection method thereof that can quickly and accurately inspect for the presence or absence of a connection failure between a cable and a connector connected to the cable. It is to provide.

According to a first aspect of the present invention, there is provided a method for inspecting a cable, the step of storing reference information serving as a reference for determining the connection state of the cable in a reference information storage unit, and a cable to be inspected are selected. (The selection of the cable is performed by, for example, an operator), searching for reference information corresponding to the selected cable from the reference information storage unit, and based on the searched reference information of the cable A step of inspecting a connection state of each pin of the first connector and the second connector connected to both ends of the cable, and based on the inspection result, the first connector and the second connector of the cable A cable inspection method comprising: displaying connection error information for each pin; Provided. The reference information includes, for example, cable information and connector information as will be described later.

A method for inspecting the cable, wherein the connection error information is one of a disconnection error, a short-circuit error, and a connection error, and the connection error information may be displayed by being divided into different hues. The disconnection means a case where the pin signal line is not connected among the pins in which the pin assignment information (connected pin information) exists. A short circuit refers to a case where pins that are not assigned according to the setting of the pin assignment information and are not connected among pins having pin assignment information are connected. The connection means a case where there is a connected pin among pins without pin assignment information.

Inspecting the connection state of each pin of the first connector and the second connector of the cable includes outputting a test signal to each pin of the first connector, and a second connector coupled to the first connector. The step of inputting a test result signal from each of the pins, the pin number of the first connector from which the test signal is output and the pin number of the second connector from which the test result signal is input And a step of determining a connection state of each pin of the first connector and the second connector based on a result of the comparison.

In the step of determining the connection state of each pin, the pin number of the first connector to which the test signal is output and the pin number of the second connector to which the test result signal is input are included in the reference information of the cable. If it does not match the included pin assignment information, it can be determined that a short circuit error has occurred in the pin numbers of the first connector and the second connector. When the pin number of the first connector to which the test signal is output and the pin number of the second connector to which the test result signal is input are pin numbers that do not exist in the pin assignment information of the cable. It can be determined that a connection error has occurred in the pin numbers of the first connector and the second connector. Further, when there is no test result signal input from the second connector, the pin number of the first connector from which the test signal is output and the pin number of the second connector from which the test result signal is input It can be determined that a disconnection error has occurred.

The cable inspection method, wherein the reference information includes at least one of a cable name, a connector name, a connector pin count, and pin assignment information, and visually identifies the cable and the connector connected to the cable. One or more images of a cable image and a connector image may be further included.

The step of retrieving the reference information of the cable is performed by reading the unique identification number of the cable stored in an RFID (Radio Frequency IDentification) tag attached to the cable or a barcode with an RFID reader or a barcode scanner. Reference information corresponding to the unique identification number can be retrieved from the reference information storage unit.

The cable inspection method includes a step of displaying an error information screen that displays whether or not the cable is defective, a pin number of the first connector and the second connector of the cable where the connection error information exists, and the connection error information. Displaying a detailed error screen for displaying the type. The detailed error screen is displayed in response to a request from an operator, for example.

The cable inspection method may further include a step of storing the inspection result of the cable.

According to a second aspect of the present invention, there is provided a device for inspecting a cable, wherein the reference information storage unit stores reference information serving as a criterion for determining the connection state of the cable, and each pin of the first connector of the cable. A test signal output unit for outputting a test signal, a test signal input unit for inputting a test result signal from each pin of the second connector connected to each pin of the first connector, a first connector of the cable, and A connection state determination unit that determines a connection state of each pin of the second connector, a display unit that displays connection error information of each pin of the first connector and the second connector of the cable, and the test signal that is output The reference information includes the pin number of the first connector and the pin number of the second connector to which the test result signal is input. The connection state determination unit is controlled so as to determine the connection state of each pin of the first connector and the second connector of the cable compared with the assignment information, and based on the determination result of the connection state determination unit, the cable And a control unit that controls the display unit so as to display connection error information of each pin of the first connector and the second connector.

In the cable inspection device, the connection error information is one of a disconnection error, a short-circuit error, and a connection error, and the control unit displays the connection error information in a different hue from each other. The display unit can be controlled.

The cable inspection apparatus further includes an inspection information storage unit that stores inspection result information of the cable, and the control unit retrieves and displays the inspection result information previously performed on the cable from the inspection information storage unit. Thus, the display unit can be controlled.

In addition, the cable inspection apparatus may further include a user input unit that receives reference information of the cable. The reference information is input by, for example, an operator.

In the cable inspection device, the control unit may control the test signal output unit to sequentially output the test signal corresponding to the number of pins of the first connector and the second connector of the cable. it can.

The control unit displays an error information screen that displays the presence / absence of a defect in the cable, a pin number of the first connector and the second connector of the cable where the connection error information exists, and details of the type of the connection error information The display unit can be controlled to display an error screen.

In addition, the control unit searches the reference information storage unit for reference information corresponding to the type of cable input from the user input unit, or a unique identification number of an RFID tag or barcode attached to the cable. Can be input from the RFID reader or the barcode scanner, and the reference information corresponding to the input unique identification number can be retrieved from the reference information storage unit.

According to a third aspect of the present invention, there is provided a method for inspecting a jig apparatus to which a cable to be inspected is connected, wherein reference information serving as a reference for determining the connection state of the cable is stored in a reference information storage unit. A step of selecting a cable connected to the jig device, a step of retrieving reference information corresponding to the selected cable from the reference information storage unit, and testing each pin of the first connector of the cable A step of sequentially outputting signals, a step of inputting a test result signal from each pin of the second connector connected to the first connector, and the output test signal and the input test result signal Determining a connection state of each circuit line of the jig device, and based on the determination result, Provided by the step of displaying the connection state information of each time line, the inspection method of the jig apparatus including a.

According to a fourth aspect of the present invention, there is provided a computer-readable recording medium on which a program for executing the cable inspection method is recorded.

According to the present invention described above, the connection state of the pin connector coupled to the cable can be inspected, and the disconnection, short circuit or connection of the cable can be automatically inspected quickly and accurately.

Further, according to the present invention of another aspect, cable connection error information can be displayed by being classified into hues different from each other depending on the type thereof, so that the operator can easily visually confirm the connection error information. .

Further, according to another aspect of the present invention, it is possible to inspect whether there is a defect in the jig apparatus using a cable that has been confirmed to have no connection error information.

It is explanatory drawing which shows the outline of a structure of the cable inspection system provided with the cable inspection apparatus which concerns on one Embodiment of this invention. It is explanatory drawing which shows the outline of a structure of the cable inspection apparatus which concerns on one Embodiment of this invention. 5 is a flowchart for explaining a method of inputting reference information of a cable according to an embodiment of the present invention. It is a figure which shows an example of the connector management screen which concerns on one Embodiment of this invention. It is a figure which shows an example of the cable management screen which concerns on one Embodiment of this invention. It is a figure which shows an example of the cable inspection screen which concerns on one Embodiment of this invention. It is an example of the detailed error screen which concerns on one Embodiment of this invention. It is a flowchart for demonstrating the cable inspection method which concerns on one Embodiment of this invention. It is a flowchart for demonstrating the inspection method of the connection state of each pin of the connector which concerns on one Embodiment of this invention. It is a flowchart for demonstrating the inspection method of the jig apparatus which concerns on one Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Cable inspection system 110 Cable inspection apparatus 111 User input part 112 Reference information storage part 113 Test signal output part 114 Test signal input part 115 Connection state judgment part 116 Display part 117 Inspection information storage part 118 Control part 120 1st interface apparatus 130 1st 2 interface device 140 jig device 141 first connector connecting portion 142 second connector connecting portion 143 connector extension connecting portion 200 connector management screen 210 connector list area 220 connector information display and input area 230 add / change / delete button area 300 cable management screen 310 Cable List Area 320 Cable Information Display and Input Area 330 Connector List Area 340 Add / Change / Delete Button Area 400 Cable Inspection Screen 41 0 Project name and operator selection area 420 Equipment name and equipment type selection area 430 Inspection cable combo box 440 Cable information area 450 Cable image 460 Pin assignment information area 470 Cable inspection result display area 480 Button selection area 500 Detailed error screen

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that a person having ordinary knowledge in the technical field to which the present invention can easily carry out. The present invention can be implemented in various different forms and is not limited to the embodiments described herein.

Hereinafter, a cable inspection device and an inspection method thereof according to an embodiment of the present invention will be described with reference to FIGS.

FIG. 1 is an explanatory diagram showing an outline of a configuration of a cable inspection system provided with a cable inspection device according to an embodiment of the present invention.

As shown in FIG. 1, the cable inspection system 100 includes a cable inspection device 110, a first interface device 120, a second interface device 130, and a jig device 140.

The cable inspection apparatus 110 includes a notebook, a desktop, a laptop, and the like, and displays a window-based (Microsoft product) graphic user interface (GUI) through a monitor.

The cable inspection device 110 is connected to the jig device 140 through the first interface device 120 and the second interface device 130, and inspects the connection state of the cable connected to the jig device 140.

The cable inspection device 110 outputs a test signal for inspecting the cable to the jig device 140. The output test signal is input as a test result signal from the jig device 140 to the cable inspection device 110 through the pins of the first connector and the second connector at both ends of the inspection cable connected to the jig device 140. The cable inspection device 110 determines the connection state of the cable based on the test result signal.

The first and

second interface devices

120 and 130 are connected to the cable inspection device 110 and the jig device 140, respectively, and transmit and receive test signals and test result signals output from the cable inspection device 110 and the jig device 140.

The jig device 140 is connected to the cable inspection device 110 through the second interface device 130 and the first interface device 120. The jig device 140 includes a first connector connecting portion 141 and a second connector connecting portion 142 to which a first connector and a second connector connected to both ends of a cable to be inspected are respectively connected.

The jig device 140 further includes a connector expansion connection part 143 for receiving and connecting connectors configured in various forms in addition to the first connector connection part 141 and the second connector connection part 142.

The jig device 140 applies the test signal input from the cable inspection device 110 through the first interface 120 and the second interface device 130 to the first connector connecting portion 141 electrically connected to the first connector of the cable. The test signal applied to the first connector connecting portion 141 is input to each pin of the first connector of the cable, and a test result signal is output from each pin of the second connector connected to each pin of the first connector by a signal line. Is output as The jig device 140 transmits the test result signal output from each pin of the second connector through the second connector connection portion 142, the second interface device 130, and the first interface 120 electrically connected to the second connector of the cable. Output to the cable inspection device 110.

FIG. 2 is an explanatory diagram showing an outline of the configuration of the cable inspection apparatus according to an embodiment of the present invention.

As shown in FIG. 2, the cable inspection device 110 includes a user input unit 111, a reference information storage unit 112, a test signal output unit 113, a test signal input unit 114, a connection state determination unit 115, and a display unit 116. And an inspection information storage unit 117 and a control unit 118.

In the user input unit 111, reference information serving as a reference for determining the connection state of the inspection cable is input by the operator. The reference information includes information on the cable, information on the connector, information on various equipment in which the cable is used, and the like.

The reference information storage unit 112 stores the reference information input by the operator, classified by cable, connector, and equipment.

The test signal output unit 113 outputs a test signal for inspecting the connection state of the cable to the jig device 140 through the first interface device 120 and the second interface device 130.

The test result signal output from the jig device 140 is input to the test signal input unit 114 through the first connector and the second connector of the cable.

The connection state determination unit 115 analyzes the input test result signal, and the connection state of each pin of the first connector and the second connector of the cable, that is, any one abnormality among the short circuit, disconnection, and connection of the inspection pin Determine the presence or absence.

At this time, the disconnection refers to the case where the pin signal line is not connected among the pins having the pin assignment information described later. A short circuit refers to a case where pins that are not assigned according to the setting of the pin assignment information and are not connected among pins having pin assignment information are connected. The connection means a case where there is a connected pin among pins without pin assignment information.

The display unit 116 displays information on the connection state of each pin of the first connector and the second connector of the cable, such as connection error information of each pin, on the screen.

The inspection information storage unit 117 stores the inspection result information of the cables that have been inspected for each cable.

The control unit 118 controls the operation of the entire cable inspection device 110, inspects the connection state for each pin of the first connector and the second connector of the cable, and displays the connection state information on the screen.

That is, the control unit 118 searches the reference information of the cable connected to the jig device 140, and causes the test signal output unit 113 to sequentially output the test signal to all the pins of the connector connected to the corresponding cable. Control. When the output test signal is output as a test result signal from the jig device 140 via the first connector and the second connector of the cable, the test result signal is input through the test signal input unit 114, and The connection state determination unit 115 is controlled so as to determine the connection state of the pins of the first connector and the second connector.

Also, the control unit 118 controls the display unit 116 so that connection state information for all the pins of the first connector and the second connector determined by the connection state determination unit 115 is displayed on the screen.

FIG. 3 is a flowchart for explaining a method of inputting cable reference information according to an embodiment of the present invention. The cable reference information is input to the user input unit 111 of the cable inspection apparatus 110 as described above.

First, in step S11, information on various connectors related to connectors connected to both ends of the cable, for example, connector names, connector images, the number of pins, etc., are input to the cable inspection device 110 by the operator. And stored in the reference information storage unit 112. At this time, the operator can input connector information through a “connector management” screen provided by the cable inspection device 110. FIG. 4 is a diagram showing an example of such a connector management screen. As shown in FIG. 4, the connector management screen 200 displays a connector list area 210 and information on the connector selected in the connector list area 210, or a connector information display and input area for inputting connector information. 220, and an add / change / delete button area 230 for adding, changing, and deleting connector management information.

Next, in step S12, the cable inspection device 110 receives information on cables related to various cables, for example, the name of the cable, the image of the cable, the type of connector connected to the cable, and the like, It is stored in the reference information storage unit 112. At this time, the operator can input cable information through a “cable management” screen provided by the cable inspection device 110. FIG. 5 is an example of such a cable management screen. As shown in FIG. 5, the cable management screen 300 includes a cable list area 310, a cable information display and input area 320 for inputting cable information, which displays or adds information on the cable selected in the cable list area 310. , A connector list area 330 for displaying information on connectors connected to the corresponding cable, and an add / change / delete button area 340 for adding, changing, and deleting cable information.

At this time, for example, if the first connector A and the second connector B connected to both ends of the cable are selected, the pin assignment information of the cable, that is, the pin information of the second connector B connected to the first connector A and the second The pin information of the first connector A connected to the connector B is displayed on the cable management screen 300.

Although it has been described that the connector information input step S11 is performed before the cable information input step S12, the present invention is not necessarily limited to this, and in the cable information input step S12, both ends of the corresponding cable are connected. Information on connectors to be connected can be added.

Next, in step S 13, equipment information relating to various equipment for which the cable is used, such as equipment name and equipment type, is input to the cable inspection device 110 and stored in the reference information storage unit 112. Thereafter, in step S14, cable link information obtained by linking the cable information used for each equipment with the equipment information input in step S13 is stored in the reference information storage unit 112.

FIG. 6 is a diagram showing an example of a cable inspection screen as an error information screen according to an embodiment of the present invention. This cable inspection screen is displayed on the display unit 116 of the cable inspection device 110.

As shown in FIG. 6, the cable inspection screen 400 includes a project name / operator selection area 410, an equipment name / equipment type selection area 420, an inspection cable combo box 430, a cable information area 440, and a cable image. 450, a pin assignment information area 460, a cable inspection result display area 470, and a button selection area 480.

The project name and worker selection area 410 is an area for selecting a project name and an operator who performs cable inspection used when performing cable inspection.

When an equipment name and equipment type are selected in the equipment name and equipment type selection area 420, a list of cables corresponding to the selected equipment and equipment type is displayed in the inspection cable combo box 430.

In the inspection cable combo box 430, a list of cables is displayed. When a cable to be inspected is selected in the inspection cable combo box 430, information on the selected cable is displayed in a cable information area 440, a cable image area 450, and a pin assignment information area 460, respectively.

The cable information area 440 displays the names of the first connector and the second connector connected to the cable selected in the inspection cable combo box 430 and the number of pins of each connector.

The cable image area 450 displays the image of the cable selected in the inspection cable combo box 430 and the image of the connector connected to the cable. By expressing the cable and the connector connected to the cable in this way, the operator can easily identify the cable to be inspected, and can prevent an error in selecting the cable and the connector.

The pin assignment information area 460 displays the pin assignment information of the cable selected in the inspection cable combo box 430. Pin information connected to the second connector B is displayed in the row of the first connector A, and pin information connected to the first connector A is displayed in the row of the second connector B. In the “connection information”, connection error information of each pin of the first connector A and the second connector B is displayed by being divided into different hues. For example, a disconnection error can be displayed in red, a short circuit error can be displayed in green, and a connection error can be displayed in blue. Thereby, the operator can visually identify the connection error information of the connector and can easily grasp the inspection result.

The cable inspection result area 470 displays the cable inspection result, that is, the presence or absence of a cable defect. If it is determined that there is no abnormality in the cable inspection result, for example, “OK” is displayed in the cable inspection result area 470. If it is determined that the cable inspection result is abnormal, the cable inspection result area 470 is displayed. For example, “NG” is displayed.

At this time, if “NG” is clicked, a “detailed error screen” is displayed in which detailed connection error information can be confirmed. FIG. 7 is an example of such a detailed error screen. As shown in FIG. 7, the detailed error screen 500 of “connection error information” displays the pin numbers and error types of the first connector A and the second connector B in which an error has occurred. For example, if “disconnection error: connector A (1) -connector B (1)” is displayed on the detailed error screen 500 of “connection error information”, the first pin of the first connector A and the first pin of the second connector B Indicates that a disconnection error has occurred where the pin lines are not connected.

As shown in FIG. 6, the button selection area 480 includes a “<<” button for moving to a previously registered cable, a “>>” button for moving to the next registered cable, and the selected cable. "Inspect" button for performing inspection, "Detail print" button for outputting the inspection result of the selected cable, "Overall information" button for displaying a screen showing all the cables inspected in the selected project, A “setting” button for displaying a setting screen for inputting reference information and an “end” button for ending the cable inspection are included.

FIG. 8 is a flowchart for explaining a cable inspection method according to an embodiment of the present invention. When performing this cable inspection method, for example, the above-described cable inspection system 100 is used.

In step S21, the cable to be inspected by the operator is selected for the cable inspection device 110.

In step S22, the cable inspection device 110 searches the reference information storage unit 112 for the reference information of the cable selected by the operator. Thereafter, the process proceeds to step S23, where the reference information of the searched cable, for example, the name of the cable, the image of the cable, the type of the connector connected to the cable, etc. is displayed on the screen. At this time, the cable inspection apparatus 110 may display information on the final inspection result together when there is information on the inspection result previously performed on the cable.

In the above-described configuration, step S22 of the cable reference information search is performed by using a radio frequency identification (RFID) tag or a barcode-attached cable as an RFID tag or a barcode scanner using an RFID reader or barcode scanner. By reading the identification number for each cable stored in the code, it is possible to automatically retrieve the reference information of the corresponding cable from the reference information storage unit 112. In this way, if the operator identifies the cable using an RFID tag or barcode instead of selecting the cable name directly, not only can the operator select a cable but also the time required for inspection can be reduced. can do.

In step S24, the cable inspection device 110 sequentially applies a test signal to each pin of the first connector and the second connector of the cable to inspect the connection state of each pin (inspection process of the connection state of each pin of the connector). Will be described later with reference to FIG.

In step S25, the cable inspection device 110 compares the energization result for each pin of the inspection target cable with the reference information of the inspection target cable, and connection error information is obtained for each pin of the first connector and the second connector. Determine if it exists.

If the result of determination in step S25 is that connection error information does not exist, processing proceeds to step S26, and the cable inspection result is stored in the inspection information storage unit 117. On the other hand, if connection error information exists, the process proceeds to step S27, and the connection error information is displayed on the screen. At this time, the cable inspection device 110 displays the connection error information of each pin of the cable in a different hue so that the operator can easily visually confirm.

FIG. 9 is a flowchart for explaining a connection state inspection method of each pin of the connector according to the embodiment of the present invention. The inspection of the connection state of each pin of the connector is an inspection performed in step S24 of FIG.

In step S31, the cable inspection apparatus 110 sequentially outputs a test signal to each pin of the first connector of the cable, and then the test result signal output from the jig apparatus 140 is input to the cable inspection apparatus 110. At this time, the test signal output in step S31 is input to the jig device 140 via the first interface device 120 and the second interface device 130. Next, the test signal input to the jig apparatus 140 is applied to each pin of the first connector of the cable connected to the first connector connection portion 141 of the jig apparatus 140. Next, the test signal applied to each pin of the first connector is output as a test result signal via each pin of the second connector connected to each pin of the first connector by pin assignment information. Next, the test result signal output from each pin of the second connector is input from the second connector connection portion 142 of the jig device 140 to the cable inspection device 110 via the second interface device 130 and the first interface device 120. The

In step S32, the cable inspection device 110 confirms the pin number of the first connector and the pin number of the second connector to which the input test result signal is applied.

In step S33, the cable inspection apparatus 110 compares whether the confirmed pin numbers of the first connector and the second connector match the pin assignment information of the cable. Thereafter, the process proceeds to step S34, and the cable inspection device 110 determines the connection state with respect to the respective pins of the first connector and the second connector, that is, the presence / absence of any one abnormality among disconnection, short circuit, and connection. .

At this time, the connection state of each pin is determined to be normal when the pin numbers of the first connector and the second connector confirmed in step S32 match the pin assignment information of the cable. . On the other hand, if the pin numbers of the first connector and the second connector confirmed in step S32 do not match the pin assignment information of the cable, it is determined that a short-circuit error has occurred in the corresponding pin number.

If the pin numbers of the first connector and the second connector confirmed in step S32 are pin numbers that do not exist in the pin assignment information of the cable, it is determined that a connection error has occurred in the corresponding pin number.

On the other hand, if there is no test signal input to the cable inspection device 110 in step S31, it is determined that a disconnection error has occurred in the corresponding pin numbers of the first connector and the second connector to which the test signal is applied.

In step S35, the cable inspection device 110 determines whether the connection state inspection for all the pins of the first connector and the second connector of the cable has been completed. If the inspection for all pins has not been completed, steps S31 to S35 are repeated until the inspection for all pins is completed. On the other hand, when the inspection for all the pins is completed, the process proceeds to step S36, and the output of the test signal is stopped.

On the other hand, if a cable that has been confirmed to have no connection error information using the cable inspection method according to an embodiment of the present invention is used, the presence or absence of a failure of the jig device 140 can also be confirmed.

FIG. 10 is a flowchart for explaining a method of inspecting a jig apparatus according to an embodiment of the present invention.

In step S41, the type of the cable connected to the first connector connecting portion 141 and the second connector connecting portion 142 of the jig device 140 is selected by the operator for the cable inspection device 110. At this time, the cable connected to the jig device 140 is a cable that has been confirmed to have no connection error information in order to check whether the jig device 140 is defective.

In step S42, the cable inspection device 140 retrieves the reference information of the selected cable from the reference information storage unit 112 and displays it on the screen.

In step S43, the cable inspection device 140 sequentially outputs a test signal to each pin of the first connector of the cable, and then proceeds to step S44 where the test result signal output from the jig device 140 is the cable inspection device 110. Is input. At this time, the test signal output in step S43 and input to the jig apparatus 140 passes through each circuit line of the jig apparatus 140, passes through each pin of the first connector and the second connector of the cable, and is a cable inspection apparatus as a test result signal. 110 is input again.

In step S45, the cable inspection device 140 determines the connection state of each circuit line of the jig device 140 based on the input test result signal. That is, the presence / absence of abnormality of each circuit line of the jig device 140 connected to each pin can be confirmed by the connection state of each pin of the first connector and the second connector of the cable.

In step S46, the cable inspection device 110 determines whether or not the inspection has been completed for all the pins of the first connector and the second connector of the cable. If the inspection has not been completed, steps S43 to S46 are repeated. Do it.

On the other hand, as a result of the determination in step S46, when the inspection for all the pins of the first connector and the second connector of the cable is completed, the process proceeds to step S47 and the output of the test signal is stopped. Thereafter, the process proceeds to step S48, and information on the circuit line of the jig apparatus 140 in which the error has occurred is displayed on the screen.

One embodiment of the present invention can be realized in the form of a recording medium including an instruction word executable by a computer, such as a program module executed by a computer. Computer readable media can be any available media that can be accessed by a computer and includes all volatile and nonvolatile media, separated and non-separated media. Also, computer readable media can include all computer storage media and communication media. Computer storage media can be volatile and non-volatile, separable and non-volatile implemented in any method or technique for storing information such as computer readable instructions, information structures, program modules or other information. Includes all separation media. Communication media typically includes computer-readable instructions, information structures, program modules, or other information in a modulated information signal such as a carrier wave, or other transmission mechanism, including any information delivery media .

Although the method and system of the present invention have been described with reference to particular embodiments, some or all of their components or operations are implemented using a computer system having a general purpose hardware architecture. be able to.

As mentioned above, although the specific embodiments have been described in the detailed description of the present invention, various modifications can be made without departing from the gist of the present invention. Therefore, the scope of rights of the present invention is not limited to the above-described embodiment, but should be determined based on the description of the claims and equivalents thereof.

The present invention is useful when inspecting a cable.

Claims

A method for inspecting a cable,
Storing reference information serving as a reference for determining the connection state of the cable in a reference information storage unit;
A step in which the cable to be checked is selected;
Searching the reference information storage unit for reference information corresponding to the selected cable;
Inspecting the connection state for each pin of the first connector and the second connector connected to both ends of the cable based on the retrieved reference information of the cable;
Displaying connection error information of each pin of the first connector and the second connector of the cable based on the inspection result;
including.
The cable inspection method according to claim 1,
The connection error information is one of a disconnection error, a short-circuit error, and a connection error, and the connection error information is displayed by being divided into different hues.
The cable inspection method according to claim 1,
Inspecting the connection state of each pin of the first connector and the second connector of the cable,
Outputting a test signal to each pin of the first connector;
A test result signal is input from each pin of the second connector connected to the first connector;
Comparing the pin number of the first connector to which the test signal is output and the pin number of the second connector to which the test result signal is input with reference information of the cable;
Determining a connection state for each pin of the first connector and the second connector based on the result of the comparison;
including.
The cable inspection method according to claim 3,
The step of determining the connection state of each pin includes
When the pin number of the first connector to which the test signal is output and the pin number of the second connector to which the test result signal is input do not match the pin assignment information included in the reference information of the cable, It is determined that a short circuit error has occurred in the pin numbers of the first connector and the second connector.
The cable inspection method according to claim 3,
The step of determining the connection state of each pin includes
When the pin number of the first connector to which the test signal is output and the pin number of the second connector to which the test result signal is input are pin numbers that do not exist in the pin assignment information of the cable, It is determined that a connection error has occurred in the pin numbers of the first connector and the second connector.
The cable inspection method according to claim 3,
The step of determining the connection state of each pin includes
When there is no test result signal input from the second connector, the pin number of the first connector to which the test signal is output and the pin number of the second connector to which the test result signal is input are disconnected. Judge that an error has occurred.
The cable inspection method according to claim 1,
The reference information includes at least one of a cable name, a connector name, a connector pin count, and pin assignment information.
The cable inspection method according to claim 7,
The reference information further includes at least one of a cable image and a connector image for visually identifying the cable and a connector connected to the cable.
The cable inspection method according to claim 1,
The step of searching the reference information of the cable includes:
The reference information storage unit stores the reference information corresponding to the unique identification number by reading the unique identification number of the cable stored in the RFID tag or barcode attached to the cable with an RFID reader or barcode scanner. Search from.
The cable inspection method according to claim 1,
Displaying an error information screen that displays the presence or absence of defects in the cable;
A step of displaying a detailed error screen displaying the pin numbers of the first connector and the second connector of the cable in which the connection error information exists and the type of the connection error information;
Is further included.
The cable inspection method according to claim 1,
The method further includes storing the inspection result of the cable.
A device for inspecting cables,
A reference information storage unit for storing reference information that is a criterion for determining the connection state of the cable;
A test signal output unit for outputting a test signal to each pin of the first connector of the cable;
A test signal input unit for inputting a test result signal from each pin of the second connector connected to each pin of the first connector;
A connection state determination unit for determining a connection state of each pin of the first connector and the second connector of the cable;
A display unit for displaying connection error information of each pin of the first connector and the second connector of the cable;
The pin number of the first connector to which the test signal is output and the pin number of the second connector to which the test result signal is input are compared with the pin assignment information included in the reference information, and the cable The connection state determination unit is controlled to determine the connection state of each pin of the first connector and the second connector, and based on the determination result of the connection state determination unit, the first connector and the second connector of the cable A control unit that controls the display unit to display connection error information of each pin;
including.
The cable inspection device according to claim 12,
The connection error information is one of a disconnection error, a short circuit error, and a connection error.
The cable inspection device according to claim 13,
The control unit controls the display unit so as to display the connection error information in a different hue.
The cable inspection device according to claim 12,
An inspection information storage unit for storing inspection result information of the cable;
The control unit controls the display unit to search and display the inspection result information previously performed on the cable from the inspection information storage unit.
The cable inspection device according to claim 12,
It further includes a user input unit for inputting reference information of the cable.
The cable inspection device according to claim 12,
The control unit controls the test signal output unit to sequentially output the test signals corresponding to the number of pins of the first connector and the second connector of the cable.
The cable inspection device according to claim 12,
The control unit displays an error information screen that displays the presence / absence of a defect in the cable, a pin number of the first connector and the second connector of the cable where the connection error information exists, and details of the type of the connection error information The display unit is controlled to display an error screen.
The cable inspection device according to claim 12,
The control unit searches the reference information storage unit for reference information corresponding to the type of cable input from the user input unit.
The cable inspection device according to claim 19,
The control unit receives the unique identification number of the RFID tag or barcode attached to the cable from an RFID reader or barcode scanner, and stores the reference information corresponding to the inputted unique identification number as the reference information. Search from the department.
A method for inspecting a jig device to which a cable to be inspected is connected,
Storing reference information serving as a reference for determining the connection state of the cable in a reference information storage unit;
A step in which the cable connected to the jig device is selected;
Searching the reference information storage unit for reference information corresponding to the selected cable;
Sequentially outputting a test signal to each pin of the first connector of the cable;
A test result signal is input from each pin of the second connector connected to the first connector;
Determining a connection state of each circuit line of the jig device based on the output test signal and the input test result signal;
Based on the determination result, displaying connection state information of each circuit line of the jig device;
including.
A computer-readable recording medium on which a program for executing a cable inspection method is recorded,
The cable inspection method includes:
Storing reference information serving as a reference for determining the connection state of the cable in a reference information storage unit;
A step in which the cable to be checked is selected;
Searching the reference information storage unit for reference information corresponding to the selected cable;
Inspecting the connection state for each pin of the first connector and the second connector connected to both ends of the cable based on the retrieved reference information of the cable;
Displaying connection error information of each pin of the first connector and the second connector of the cable based on the inspection result;
including.