JP4284962B2 - Electrical component inspection method and apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrical component inspection method and apparatus capable of inspecting an assembly error of an electrical component attached to a vehicle and whether or not the operation is normal when the electrical component is attached.
[0002]
[Prior art]
In recent years, with the advancement of electronics, vehicles such as automobiles are equipped with electronic control devices (hereinafter referred to as “ECUs”) for controlling vehicles such as engine control, transmission control, steering control, and ABS control. Yes. In general, the final process of vehicle assembly involves all attached ECU There is a step of inspecting whether there is no assembly error or whether these ECUs operate normally using an inspection device (hereinafter referred to as “external inspection device”) provided outside the vehicle.
[0003]
For example, in Patent Document 1 below, ECU An inspection method is disclosed. Slightly different control when the vehicle type is the same but the vehicle grade is different ECU May be installed. In this case, it really fits the vehicle ECU It is difficult to inspect whether the vehicle is attached after the vehicle is assembled. Therefore, in Patent Document 1 below, this ECU So that it can be easily judged even after assembly of the vehicle, ECU An identification number is stored in advance, and at the time of inspection, an identification number corresponding to the grade of the vehicle is obtained from the inspection computer. ECU And the sent identification number ECU Assembling errors can be judged by confirming the coincidence with the identification number.
[0004]
[Patent Document 1]
Japanese Patent Laid-Open No. 11-201873
[0005]
[Problems to be solved by the invention]
However, the general external inspection apparatus described in Patent Document 1 has the following problems.
[0006]
Generally all ECU This inspection is performed in the final process of assembling the vehicle. For this reason, an ECU assembly error and abnormal operation thereof are collectively detected after all the assembly operations are completed. In the unlikely event that an abnormality is found, it is necessary to dismantle the completed vehicle in the backup process in order to perform repair work such as replacing the ECU. Therefore, the renovation work takes a lot of man-hours.
[0007]
Also, after assembly ECU Check whether the ECU This is performed by outputting a command for causing the self-diagnosis to execute and receiving the result of the self-diagnosis. Instructions for carrying out self-diagnosis and the results of self-diagnosis ECU And an external inspection device via a network. For this reason, even if the test results show an abnormality, ECU It may be caused by application software installed in the network, network line connection failure, or transmission failure. ECU We cannot conclude that it came out due to the hardware of the main body.
[0008]
The present invention has been made in view of the above problems, and its purpose is as follows. ECU It is possible to provide an electrical component inspection method and apparatus capable of facilitating repair work by making it possible to inspect assembly errors and normality of operation at the time of assembly.
[0009]
[Means for Solving the Problems]
A first invention for solving the above-described problems and achieving the object is an electrical component inspection method for inspecting compatibility and operability of electrical components assembled in a vehicle, wherein the vehicle in the electrical component assembly step A step of assembling the electrical component to the vehicle, a step of notifying the completion of the assembly before the vehicle is moved from the electrical component assembly step to the next step after the assembly is completed, and the vehicle receiving the notification to the next step. Inspecting the compatibility and operability of the electrical component before moving it to The steps of inspecting the compatibility and operability of the electrical components include the steps of identifying the electrical component assembly process that has notified the end of the assembly of the electrical components and the assembly of the electrical components in the identified electrical component assembly process. The step of recognizing the type and number of electrical components that have been installed and that should be assembled to the vehicle and the type and number of electrical components that are assembled to the vehicle are compatible with the type and number of electrical components that should be assembled A step for judging whether or not an electrical component judged to be compatible is functioning normally, and a step for checking the operability of the electrical component. A step of giving a pseudo signal for operating the determined electrical component to the electrical component; a step of operating the electrical component by the pseudo signal; and whether the operation is normal Including the step of determining, the It is characterized by that.
[0010]
The second invention is an electrical component inspection apparatus for inspecting the compatibility and operability of electrical components assembled in a vehicle, and after the assembly of the electrical components to the vehicle is completed in the electrical component assembly process, An assembly completion signal output means for outputting an assembly completion signal before moving the vehicle from the electrical component assembly process to the next process; an end process detection means for detecting the electrical component assembly process from which the assembly completion signal is output; When an assembly completion signal is output, an inspection execution means is provided for executing an inspection of compatibility and operability of the assembled electrical component according to the inspection content for the electrical component assembly process detected by the termination process detection unit. The inspection execution means should be assembled in the electrical component assembly process, and an assembly component information input means for receiving assembly component information of the electrical component assembled in the electrical component assembly process when the end signal is output. Assembling scheduled part information storage means for storing the assembling scheduled part information of the electrical component, and suitability detecting means for detecting the suitability of the electrical component by comparing the assembling part information and the assembling scheduled part information. And the inspection execution means operates in place of an electrical component that has not yet been assembled, thereby performing an operability inspection of the assembled electrical component. A command is issued to execute the specified operation, and electrical components that have not yet been assembled are output. By outputting a pseudo signal instead of a signal to an assembled electrical component, the operability check of the assembled electrical component is executed, and the operability check of the electrical component is performed except when performing the operability check of the electrical component. Power control means for stopping power supply It is characterized by having.
[0011]
【The invention's effect】
According to the first invention, when the assembly of the electrical component in the electrical component assembly process is completed, the compatibility and operability of the assembled electrical component are inspected, so that the repair work is immediately performed in the electrical component assembly process. This can facilitate the repair work.
[0012]
According to the second invention, at the end of the electrical component assembly process, the compatibility and operability inspection of the assembled electrical component is executed according to the inspection content to be executed. It is possible to make the repair work easier.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0014]
FIG. 1 is a diagram showing a vehicle assembly process to which the present invention is applied.
[0015]
The vehicle assembly process includes a leading process K0 and a plurality (five in the present embodiment) of electrical component assembly steps K1 to K5 that assemble one or more electrical components to the vehicle. Here, the electrical component includes an electronic control unit (ECU) and a harness. The electrical component inspection apparatus according to the present invention includes a host computer 100, an inspection device 200 attached to a vehicle, a component storage device 300 (301 to 305) installed in each of the electrical component assembly steps K1 to K5, and each electrical component. And portable terminal devices 400 (401 to 405) carried by workers M1 to M5 in the assembling steps K1 to K5.
[0016]
The vehicle to be assembled is sequentially transferred to the electrical component assembling processes K1 to K5 after the inspection device 200 is attached in the leading process K0. In each electrical component assembly process K1 to K5, electrical components are assembled by the workers M1 to M5. In each of the electrical component assembly steps K1 to K5, when the electrical component is assembled, the operator operates the portable terminal device 400 to notify the inspection device 200 that the operation has been completed. Upon receiving this notification, the inspection apparatus 200 performs an erroneous assembly inspection (compatibility inspection) and an electrical function inspection (operability inspection) described later. The results of these inspections are notified to the operator. If there is an abnormality, repair work is immediately performed in the electrical component assembly process, and if there is no abnormality, the vehicle is transported to the next electrical component assembly process. Information necessary for the inspection is input from the host computer 100, the component storage device 300, and the portable terminal device 400 to the inspection device 200 by wireless communication.
[0017]
Next, each component of the electrical component inspection apparatus according to the present invention will be described.
[0018]
The host computer 100 creates various types of information necessary for vehicle production based on customer order information. And according to the transmission request | requirement of the test | inspection apparatus 200, the said various information is wirelessly transmitted to the test | inspection apparatus 200 via a network. The various types of information include vehicle information (information such as chassis number, model, option, etc.) in addition to scheduled assembly component information, in-vehicle network configuration information, and component pseudo signal information used for inspection. Here, the scheduled assembly component information is information indicating the electrical component to be assembled in each of the electrical component assembly steps K1 to K5, and the in-vehicle network configuration information and the component pseudo signal information are various information used for the electrical component inspection.
[0019]
FIG. 2 is a block diagram showing a configuration of the inspection apparatus 200. In FIG. 2, the inspection apparatus 200 is connected to an electrical component group of a vehicle to be assembled (hereinafter referred to as “vehicle-mounted network”) via a diagnostic connector 201.
[0020]
The inspection apparatus 200 includes a CPU 210 that controls each part of the apparatus and performs various arithmetic processes according to a program. Connected to the CPU 210 are a ROM 220, a RAM 230, a wireless interface 241, an input interface 242, an output interface 243, a driver / receiver circuit 250, and a switching circuit 270.
[0021]
The ROM 220 is a storage unit that stores various programs and parameters in advance, and stores an electrical component inspection program in the present embodiment. Here, the electrical component inspection program is a program for executing an erroneous assembly inspection and an electrical function check described later. The RAM 230 is a storage unit that temporarily stores programs and data as a work area. Here, the data includes assembly part information input from the host computer 100, in-vehicle network configuration information, and part pseudo signal information, and the RAM 230 functions as an assembly part information storage unit.
[0022]
The wireless interface 241 is a wireless input / output interface for wirelessly exchanging data with external devices such as the host computer 100 and the portable terminal device 400. The input interface 242 is an interface for receiving an input from an external device, and the output interface 243 is an interface for transmitting an output to the external device. In this embodiment, an operation button is connected to the input interface 242, and a display device is connected to the output interface 243.
[0023]
The driver / receiver circuit 250 is a circuit that converts an output signal of the CPU 210 into a signal for input to the electrical component, and converts an output signal of the electrical component into a signal for input to the CPU 210. The output signal of the CPU 210 is converted into a signal by the driver / receiver circuit 250 and then input to the electrical component via the gateway circuit 260. The output signal of the electrical component is input to the driver / receiver circuit 250 via the gateway circuit 260, converted into a signal, and then input to the CPU 210.
[0024]
The switching circuit 270 is a circuit for controlling ON / OFF of power supply from the power supply circuit 280 to each electrical component based on a command from the CPU 210. Here, the power supply circuit 280 is also a power supply for the inspection apparatus 200 and includes a battery.
[0025]
FIG. 3 is a block diagram illustrating a configuration of the component storage device 300. In the present embodiment, the component storage apparatus 300 includes a plurality of storage boxes 311 to 314, take-out detection switches 321 to 324 provided corresponding to the storage boxes 311 to 314, an assembly component information generation unit 330, and A shelf provided with a wireless interface 340.
[0026]
The storage boxes 311 to 314 store predetermined electrical components. The take-out detection switches 321 to 324 are switches for detecting that an electrical component has been taken out from the storage boxes 311 to 314. Examples of the extraction detection switches 321 to 324 include a limit switch, a phototube switch, and the like, but are not limited thereto. The assembly component information generation unit 330 generates assembly component information as information on the electrical components assembled in the electrical component assembly process based on the detection signals of the take-out detection switches 321 to 324. The wireless interface 340 is an interface for wirelessly transmitting the assembly component information to the portable terminal device 400.
[0027]
FIG. 4 is a block diagram illustrating a configuration of the portable terminal device 400. The portable terminal device 400 includes a CPU 410, and a ROM 420, a RAM 430, a wireless interface 440, an end notification operation unit 450, and a power supply circuit 460 are connected to the CPU 410. A general description of these will be omitted to avoid duplication. The wireless interface 440 is an interface that accepts assembly component information from the component storage apparatus 300. The RAM 430 stores the assembly part information. The ROM 420 stores in advance end process information indicating an electrical component assembly process to which the portable terminal device 400 belongs. This end process information is used in an erroneous assembly inspection and an electrical function inspection described later. The end notification operation unit 450 is a means for instructing the end of the electrical component assembling process to which the worker carrying the portable terminal device 400 belongs. In this embodiment, a push button is used. In response to the pressing operation of the operator, the end notification operation unit 450 sends an end signal indicating the end of the electrical component assembly process to the CPU 410. The wireless interface 440 also functions as an interface for wirelessly transmitting the end signal, the end process information, and the assembly part information stored in the RAM 430 to the inspection apparatus 200. Correspondingly, the wireless interface 241 of the inspection apparatus 200 described above receives an end signal indicating the end of the electrical component assembly process and receives assembly component information each time each electrical component assembly process is completed.
[0028]
Next, the procedure of the entire vehicle assembly process in the present embodiment will be described together with the operation procedure of the electrical component inspection apparatus.
[0029]
FIG. 5 is a flowchart showing a procedure of the entire vehicle assembly process in the present embodiment.
[0030]
In the first step K0, information related to the vehicle to be assembled is input from the host computer 100 to the inspection apparatus 200 and stored in the RAM 230 of the inspection apparatus 200 (S101). Information related to the vehicle includes assembly-scheduled component information, in-vehicle network configuration information, and component pseudo signal information.
[0031]
After the inspection device 200 is attached to the vehicle (S102), the vehicle is transported to the next process (S103). In the electrical component assembly process, the electrical component assembly operation is performed by the operator (S104). When the assembling work is completed, the inspection apparatus 200 executes an electrical component inspection program (S105). If the operability of the electrical component is abnormal as a result of the execution of the program (S106: NO), after the modification work such as replacement, addition, and removal of the electrical component is performed (S107), the process proceeds to step S105. To do. If the operability of the electrical component is normal (YES in S106), it is determined whether all the electrical component assembly steps have been completed (S108). If there is an electrical component assembly process that has not been completed (S108: NO), the vehicle is transported to the next process (S103). When all the electrical component assembly steps have been completed (YES in S108), the vehicle assembly step of the present embodiment ends.
[0032]
Next, the operation procedure of the electrical component inspection apparatus accompanying the assembly work of the electrical component in each electrical component assembly process, that is, the operation procedure of the electrical component inspection apparatus in step S104 of FIG. 5 will be described in more detail.
[0033]
FIG. 6 is a flowchart showing a procedure of the operation of the component storage device 300 associated with the assembling operation of the electrical component. In FIG. 6, the component storage device 300 waits until one of the take-out detection switches 321 to 324 outputs a detection signal, that is, until an operator takes out an electrical component from one of the storage boxes 311 to 314 (S201: NO). When any one of the detection detection switches 321 to 324 outputs a detection signal (S201: YES), the assembly component information generation unit 330 generates assembly component information based on the detection signals received from the extraction detection switches 321 to 324. (S202). In the present embodiment, the assembly component information is a component number of the extracted electrical component. More specifically, the assembly component information generation unit 330 stores in advance a correspondence table between the extraction detection switches 321 to 324 and the part numbers, and receives from the extraction detection switches 321 to 324 based on the correspondence table. The detection signal is converted into a part number. Next, the wireless interface 340 of the component storage device 300 wirelessly transmits the assembly component information received from the assembly component information generation unit 330 to the portable terminal device 400 (S203), and then prepares for the removal of the next electrical component (S201). ).
[0034]
FIG. 7 is a flowchart showing an operation procedure of the portable terminal device 400 in association with the assembling work of the electrical component. In FIG. 7, the portable terminal device 400 determines whether or not assembly component information from the component storage device 300 has been received by the wireless interface 440 (S301). If assembly part information has not been received (S301: NO), the process proceeds to step S303. When assembly part information is received (S301: YES), the assembly part information is stored in the RAM 430 (S302). Next, it is determined whether or not the end notification operation unit 450 has been pressed (S303). Here, the end notification operation unit 450 is pressed by the operator when the assembling work of the electrical components in each electrical component assembling process is completed. When the end notification operation unit 450 is not pressed (S303: NO), the process returns to step S301. With the above operation, the assembly component information received until the end notification operation unit 450 is pressed is successively accumulated in the RAM 430. When the end notification operation unit 450 is pressed (S303: YES), the end signal, the end process information indicating the electrical component assembly process to which the portable terminal device 400 belongs, and the assembly component information stored in the RAM 430, Are wirelessly transmitted to the inspection apparatus 200 through the wireless interface 440 (S304). Next, all assembly part information stored in the RAM 430 is cleared (S305), and the next vehicle assembly work is prepared (S301).
[0035]
FIG. 8 is a flowchart showing the procedure of the operation of the inspection apparatus 200 associated with the assembling work of the electrical components. In FIG. 8, the inspection apparatus 200 stands by until an end signal, end process information, and assembly part information are received from the portable terminal apparatus 400 via the wireless interface 241 (S401: NO). When the end signal, the end process information, and the assembly part information are received (S401: YES), the end process information and the assembly part information are stored in the RAM 230 (S402). Thereafter, the inspection apparatus 200 starts to execute the electrical component inspection program (S105 in FIG. 5).
[0036]
Next, the procedure for executing the electrical component inspection program by the inspection apparatus 200 will be described in detail.
[0037]
FIG. 9 is a flowchart showing a procedure of the operation of the CPU 210 in executing the electrical component inspection program. The electrical component inspection program is a program for the inspection device 200 to perform an erroneous assembly inspection and an electrical function inspection. Here, in the incorrect assembly inspection, it is inspected whether or not an electrical component to be assembled is assembled to a vehicle to be assembled, and whether or not an electrical component that should not be assembled is assembled to the vehicle. . In the electrical component inspection, it is inspected whether the operability of the electrical component and the entire vehicle-mounted network is normal.
[0038]
First, the CPU 210 performs an erroneous assembly inspection in order to inspect compatibility (S501). For this erroneous assembly inspection, the scheduled assembly part information, the end process information, and the assembled part information stored in the RAM 230 are used. FIG. 10 is a diagram illustrating an example of assembly-part information. In FIG. 10, the scheduled assembly component information is composed of records corresponding to one or more electrical components to be assembled in each electrical component assembly process K1 to K5. This record includes an electrical component assembly process field indicating an electrical component assembly process in which the electrical component is to be assembled, and a component number field indicating the component number of the electrical component. The CPU 210 recognizes the completed electrical component assembly process based on the completion process information, and compares the component number corresponding to the completed electrical component assembly process in the scheduled assembly component information with the component number of the assembly component information. As a result of the comparison, if both match, the assembled part is suitable for the vehicle, and there is no excess or deficiency of the assembled parts, so it is determined that there is no misassembly. If the two do not match, the assembled part is not suitable for the vehicle, or there is an excess or deficiency, so it is determined that “there is an incorrect assembly”. The erroneous assembly inspection will be described more specifically with reference to FIG. If the end process information is “K4” and the assembly part information is as shown in FIG. 11A, it is determined that there is no excess or deficiency in the assembly parts and “no misassembly”. If it is as shown in FIG.11 (b), since there is a lack of parts corresponding to "E13", it is determined that "there is a wrong assembly". If it is as FIG.11 (c), since the part corresponding to part number "E20" is extra, it will be judged that there exists an error.
[0039]
When the determination result of the incorrect assembly inspection is “with incorrect assembly” (S502: NO), the part number corresponding to the missing or incompatible part or the part number corresponding to the extra part is displayed on the output interface 243. To the display device (S510). In response to this, the display device displays the result of the erroneous assembly inspection. Thereby, the operator can know that there was an excess or deficiency or non-conformity of the electrical components, and the part number corresponding to the component related to the excess or deficiency or non-conformity.
[0040]
On the other hand, when the determination result of the incorrect assembly inspection is “no incorrect assembly” (S502: YES), it is determined whether or not the electrical function inspection is necessary (S503). For this determination, the in-vehicle network configuration information and end process information stored in the RAM 230 are used. FIG. 12 is a diagram illustrating an example of in-vehicle network configuration information. In FIG. 12, the in-vehicle network configuration information includes a plurality of records corresponding to a plurality of electrical components connected to the in-vehicle network. This record includes an electrical component assembly process field indicating an electrical component assembly process in which the electrical component is to be assembled, an inspection necessity field indicating whether or not an electrical function test needs to be performed on the electrical component, and the electrical component And a self-diagnosis function field indicating whether or not the part has a self-diagnosis function. The CPU 210 recognizes the completed electrical component assembly process from the end process information, and refers to the information in the inspection necessity field of the record corresponding to the completed electrical component assembly process in the in-vehicle network configuration information. As a result of the reference, if all are “none”, it is determined that “no inspection is necessary”. If there is even one “exist”, it is determined that “inspection is necessary”. The determination will be described more specifically with reference to FIG. When the end process information is “K1”, since the inspection necessity fields of the record whose electric component assembly process field is “K1” in FIG. 12 are all “none”, it is determined that “no inspection necessity”. When the end process information is “K2”, since “exist” exists in the inspection necessity field of the record whose electric component assembly process field is “K2” in FIG. 12, it is determined that “inspection is necessary”.
[0041]
If the result of the determination is “no inspection required” (S503: NO), a signal indicating normality is output to the display device via the output interface 243 (S510). In response to this, the display device displays that it is normal. On the other hand, if the result of the determination is “there is a need for inspection” (S503: YES), a power ON command is output to the switching circuit 270 (S504). Thereby, power supply from the power supply circuit 280 to the in-vehicle network is started.
[0042]
Next, a self-diagnosis test is executed (S505). This self-diagnosis inspection is to confirm whether or not there is an abnormality in the electrical component main body using the self-diagnosis function of the electrical component, and is executed as follows. In-vehicle network configuration information and end process information stored in the RAM 230 are used for the self-diagnosis test. The CPU 210 recognizes the completed electrical component assembly process based on the end process information. Then, in the in-vehicle network configuration information, the electrical component assembly process field refers to the self-inspection function field of the record that is the completed electrical component assembly process. As a result of the reference, if the information in the self-diagnosis function field is “present”, a command is issued to perform a self-diagnosis inspection for all electrical components. Then, by receiving the inspection result from the electrical component, it is confirmed whether or not there is an abnormality in the electrical component body. The execution of the self-diagnosis test will be described more specifically with reference to FIG. It is assumed that the end process information is “K2”. When referring to the self-diagnosis function field of the record whose electrical component assembly process field is “K2” in the in-vehicle network configuration information of FIG. 12, the electrical components corresponding to the part numbers “E02” and “E03” have a self-diagnosis function. I understand. Therefore, a command is issued to perform a self-diagnosis test on the electrical components corresponding to the part numbers “E02” and “E03”.
[0043]
If the diagnostic result received from any of the electrical components is abnormal as a result of the self-diagnosis test (S506: NO), the part number corresponding to the component whose diagnostic result is abnormal is displayed via the output interface 243. The data is output to the device (S510). In response to this, the display device displays the result of the self-diagnosis test. As a result, the operator can know that there is an abnormality in the electrical component main body and the part number corresponding to the abnormal part.
[0044]
On the other hand, if all the diagnostic results received from the electrical components are normal as a result of the self-diagnosis test (S506: YES), the in-vehicle network diagnostic test is executed (S507). This in-vehicle network diagnostic inspection confirms whether or not there is an abnormality in the operation of the entire in-vehicle network. At the end of the electrical component assembly steps K1 to K4, there are electrical components that are scheduled to be assembled in the subsequent electrical component assembly step but have not yet been assembled. Therefore, the inspection device 200 operates as a driver instead of an electrical component that has not yet been assembled, thereby confirming whether the operation of the entire in-vehicle network is normal and checking the operability of the assembled electrical component. Execute. In this embodiment, the CPU 210 generates a pseudo signal instead of the output signal of the electrical component that has not yet been assembled and outputs it to the assembled electrical component, so that there is no abnormality in the operation of the entire in-vehicle network. Confirm. The in-vehicle network diagnostic test is executed as follows. For in-vehicle network diagnosis inspection, in-vehicle network configuration information, end process information, and component pseudo signal information stored in the RAM 230 are used. Based on the end process information, the electrical component assembly process completed immediately before the end signal is input is recognized, and the assembled electrical component and the electrical component not yet assembled are confirmed based on the in-vehicle network configuration information. Then, a command is issued to execute a predetermined operation on all the electrical components that have been assembled. Further, in order to operate in place of an electrical component that has not yet been assembled, a pseudo signal having a predetermined magnitude is output to a predetermined assembled electrical component at a predetermined timing based on the component pseudo signal information. Here, the component pseudo signal information is information in which an electrical component is associated with information on a pseudo signal to be output by the CPU 210 when the electrical component is not assembled. The information of the pseudo signal is information necessary for outputting the information of the electrical component of the output destination, the output timing, the output size, and other pseudo signals. At the same time, a response signal is received from the assembled electrical component. Then, whether the operation of the entire in-vehicle network is normal or abnormal is determined based on whether or not the response signal from the assembled electrical component is correct.
[0045]
Next, a power OFF command is output to the switching circuit 270 (S508). Thereby, the power supply from the power supply circuit 280 to the in-vehicle network is stopped. If the result of the in-vehicle network diagnostic test is abnormal (S509: NO), the fact that the diagnostic result is abnormal is output to the display device via the output interface 243 (S510). In response to this, the display device displays that there is an abnormality in the in-vehicle network. Thereby, the worker can know that there was an abnormality in the in-vehicle network.
[0046]
On the other hand, when the result of the in-vehicle network diagnostic test is normal (S509: YES), the fact that all the test results are normal is output to the display device via the output interface 243 (S510). In response to this, the display device displays that all the inspection results are normal. Thereby, the operator can know that the result of all the inspections was normal.
[0047]
In the above embodiment, the CPU 210, the wireless interface 241 and the RAM 230 in FIG. 2, steps S401 and S402 in FIG. 8, and steps S505 and S507 in FIG. The CPU 210 and RAM 230 in FIG. 2 and steps S505 and S507 in FIG. 9 correspond to inspection execution means. The CPU 210, wireless interface 241 and RAM 230 in FIG. 2, steps S401 and S402 in FIG. 8, and step S501 in FIG. The CPU 210 in FIG. 2 and step S501 in FIG. 9 correspond to the assembly error detection means. The CPU 210 and the switching circuit 270 in FIG. 2 and steps S504 and S508 in FIG. 9 correspond to power control means.
[0048]
This embodiment has the following effects.
[0049]
(A) Since an incorrect assembly inspection is performed after the completion of each electrical component assembly process, it is possible to detect the excess and deficiency of the electrical components and the suitability for each electrical component assembly process. As a result, the operator can recognize the excess and deficiency and compatibility of the electrical parts on the spot, and if there is any excess or deficiency or non-conformity, the worker can immediately perform repair work such as removal or addition of parts It becomes like this. As a result, the repair work in the vehicle assembly process is facilitated.
[0050]
(B) Since the electrical function inspection is performed after the end of each electrical component assembly process, an abnormality in the operability of the electrical component can be detected for each electrical component assembly process. As a result, the operator can recognize the abnormal operation of the electrical component on the spot, and if there is an abnormality, the worker can immediately perform repair work such as replacement of the component on the spot. As a result, the repair work in the vehicle assembly process is facilitated.
[0051]
(C) Since the self-diagnosis inspection and the in-vehicle network diagnosis inspection are performed as the electric equipment function inspection, it is possible to detect the presence / absence of abnormality of the electric component alone and the abnormality of the entire in-vehicle network. As a result, the worker can perform appropriate repair work according to the abnormality.
[0052]
(D) After completion of each electrical component assembly process, the completed electrical component assembly process is detected, and an electrical function test is performed according to the inspection content to be executed at the end of the electrical component assembly process. It is possible to carry out an electrical function check according to the state of the electrical component.
[0053]
(E) Since the inspection device 200 operates as a driver instead of an electrical component that has not been assembled yet, the operability inspection of the assembled electrical component is executed, so that the in-vehicle network is not completed. The overall operation can be confirmed.
[0054]
(F) Since power is supplied to the in-vehicle network only when the electrical function test is performed, the assembly work of live electrical components can be eliminated, ensuring the safety of workers, and failure of electrical components due to surge noise, etc. Occurrence can be prevented.
[0055]
(G) Since information necessary for erroneous assembly inspection and electrical function inspection is input from the host computer 100 to the inspection apparatus 200 by wireless communication, information corresponding to the specification of the vehicle to be assembled can be easily input to the inspection apparatus 200. This reduces the burden on the operator.
[0056]
(H) Since the assembly component information is input from the component storage device 300 to the inspection device 200 via the portable terminal device 400 by wireless communication, the input of the assembly component information can be automated and the burden on the operator is reduced.
[0057]
(I) Since the end signal is input from the portable terminal device 400 to the inspection device 200 by wireless communication, the worker can start the electrical component inspection only by operating the end notification operation unit 450 of the portable terminal device 400. This reduces the burden on the operator.
[0058]
In addition, embodiment is not limited to said embodiment, For example, you may change as follows.
[0059]
The input of the end process information is accepted, and the electrical component assembly process completed based on the end process information is detected, but the completed electrical component assembly process is detected by counting the number of input of the end signal. Also good.
[0060]
In addition, in order to operate in place of electrical components that have not been assembled yet, it was decided to output a pseudo signal to the electrical components that had been assembled in place of the output signals of electrical components that were not yet assembled. A corresponding simulation inspection module program may be stored in advance, and the CPU 210 may execute a simulation inspection module program corresponding to an electrical component that has not yet been assembled. In this case, the CPU 210 may not only output a pseudo signal but also perform signal reception and arithmetic processing instead of an electrical component that has not yet been assembled.
[0061]
Further, the assembly component information is input from the component storage device 300 to the inspection device 200 via the portable terminal device 400. However, the portable terminal device 400 has data (ID information) indicating the component storage device 300, This ID information may be transmitted to the inspection apparatus 200, and the inspection apparatus 200 may acquire assembly component information directly from the component storage apparatus 300 corresponding to the ID information.
[0062]
In addition, various information necessary for the erroneous assembly inspection and the electrical function inspection is received from the host computer 100 or the portable terminal device 400 by wireless communication, but may be received from an input unit such as a keyboard.
[Brief description of the drawings]
FIG. 1 is a diagram showing a vehicle assembly process to which an electrical component inspection apparatus is applied.
FIG. 2 is a block diagram showing a configuration of an inspection apparatus.
FIG. 3 is a block diagram illustrating a configuration of a component storage device.
FIG. 4 is a block diagram showing a configuration of a portable terminal device.
FIG. 5 is a flowchart of the entire vehicle assembly process.
FIG. 6 is a flowchart showing a procedure of operation of the component storage device that accompanies an electrical component assembly operation.
FIG. 7 is a flowchart showing an operation procedure of the portable terminal device in association with the assembling operation of the electrical component.
FIG. 8 is a flowchart showing a procedure of an operation of the inspection apparatus associated with the assembling work of the electrical component.
FIG. 9 is a flowchart showing the procedure of the operation of the CPU in executing the electrical component inspection program.
FIG. 10 is a diagram showing an example of assembling part information.
FIG. 11 is a diagram showing an example of assembly part information for explaining an erroneous assembly inspection;
FIG. 12 is a diagram showing an example of in-vehicle network configuration information.
[Explanation of symbols]
100 Host computer
200 Inspection equipment
201 Diagnostic connector
210 CPU
220 ROM
230 RAM
241 Wireless interface
242 Input interface
243 Output interface
250 Driver / receiver circuit
260 Gateway circuit
270 switching circuit
280 Power supply circuit
300 Parts storage device
311 to 314 storage box
321 to 324 Take-out detection switch
330 Assembly part information generation unit
340 Wireless interface
400 Portable terminal device
410 CPU
420 ROM
430 RAM
440 wireless interface
450 End notification operation section
460 Power supply circuit

Claims (2)

An electrical component inspection method for inspecting compatibility and operability of an electrical component assembled in a vehicle,
Assembling the electrical component to the vehicle in an electrical component assembly step;
Informing the end of assembly before moving the vehicle from the electrical component assembly process to the next process after the assembly is completed;
Receiving the notification and inspecting the compatibility and operability of the electrical components before moving the vehicle to the next process;
Only including,
Inspecting the compatibility and operability of the electrical component includes
Identifying the electrical component assembly process that has notified the end of assembly of the electrical component; and
Recognizing the type and number of electrical components assembled to the vehicle and to be assembled to the vehicle in the identified electrical component assembly step;
Determining the suitability if the type and number of electrical components assembled to the vehicle match the type and number of electrical components to be assembled; and
A step of inspecting whether or not an electrical component determined to be compatible functions normally,
Including
Testing the operability comprises:
Providing the electrical component with a pseudo signal for operating the electrical component determined to be compatible;
Actuating the electrical component by the pseudo signal;
Determining whether the operation is normal;
Electrical parts inspection method, which comprises a. An electrical component inspection device for inspecting compatibility and operability of electrical components assembled in a vehicle,
An assembly completion signal output means for outputting an assembly completion signal before the vehicle is moved from the electrical component assembly process to the next process after the assembly of the electrical components to the vehicle is completed in the electrical component assembly process;
An end process detection means for detecting the electrical component assembly process from which the assembly end signal is output;
When the assembly completion signal is output, the inspection execution means for performing the compatibility and operability inspection of the assembled electrical component according to the inspection content for the electrical component assembly process detected by the termination process detection unit;
I have a,
The inspection execution means includes
When the end signal is output, assembly component information input means for receiving assembly component information of the electrical component assembled in the electrical component assembly step;
Assembling scheduled part information storage means for storing assembling scheduled part information of the electrical component to be assembled in the electrical component assembling step;
Suitability detection means for detecting suitability of an electrical component by comparing the assembled component information and the scheduled assembly component information;
Have
The inspection execution means performs an inspection of the operability of the assembled electrical component by operating in place of the electrical component not yet assembled,
The inspection execution means issues a command to execute a predetermined operation on the assembled electrical component, and outputs a pseudo signal to the assembled electrical component instead of the output signal of the electrical component not yet assembled. By checking the operability of the assembled electrical parts,
An electrical component inspection apparatus comprising power control means for stopping the supply of electric power to the electrical component, except when the operability test of the electrical component is executed .

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