CN111984528A

CN111984528A - Test method and device for machine equipment

Info

Publication number: CN111984528A
Application number: CN202010706155.2A
Authority: CN
Inventors: 刘丹
Original assignee: Beijing Naura Microelectronics Equipment Co Ltd
Current assignee: Beijing Naura Microelectronics Equipment Co Ltd
Priority date: 2020-07-21
Filing date: 2020-07-21
Publication date: 2020-11-24

Abstract

The application provides a test method and a test device for machine equipment, which comprise the following steps: loading a first configuration file, wherein the first configuration file stores a first incidence relation between a trigger event CEID of machine equipment and production process data SVID of the machine equipment; loading a second configuration file, wherein the second configuration file is used for loading production process data of the machine equipment; judging whether the machine equipment is connected with the machine equipment, and if so, initializing the machine equipment by using the first configuration file; after the initialization of the machine equipment is completed, testing the preset production flow of the machine equipment by using the first configuration file and the second configuration file according to a preset production time sequence so as to solve the problem that the current manufacturer cannot simulate an equipment automation control system to perform automatic production testing.

Description

Test method and device for machine equipment

Technical Field

The present disclosure relates to the field of testing technologies, and in particular, to a method and an apparatus for testing a device.

Background

At present, the semiconductor chip manufacturer realizes the automatic production by the manufacturing execution system MES system, the automatic material handling system AMHS system and the equipment automation control system EAP.

At present, a semiconductor chip manufacturer generally uses FASTsim test software to simulate an EAP system to realize testing of automatic production of equipment, specifically, during the automatic testing process of the FASTsim test software, the FASTsim test software needs to manually issue control instructions one by one according to a production sequence to realize testing of automatic production of the EAP system, but the semiconductor chip manufacturer also tries to build a simulated EAP system by itself to realize an automatic production process, but none of them is realized, the main reason is that the automatic production process of building the simulated EAP system is a cured program, only instructions in a uniform format can be identified, so that different formats issued at different times for the same instruction cannot be identified, and thus the semiconductor chip manufacturer cannot simulate the equipment automatic control system to perform automatic production testing, and therefore only can rely on the combination of the FASTsim test software and manual mode, and the test of automatic production by the equipment automatic control system is realized.

Disclosure of Invention

The application provides a test method and a test device for machine equipment, which aim to solve the problem that at present, manufacturers cannot simulate an equipment automation control system to carry out automatic production test.

In order to solve the technical problem, the application discloses a method for testing a machine equipment, which comprises the following steps:

loading a first configuration file, wherein the first configuration file stores a first incidence relation between a trigger event CEID of machine equipment and production process data SVID of the machine equipment;

loading a second configuration file, wherein the second configuration file is used for loading production process data of the machine equipment;

judging whether the machine equipment is connected with the machine equipment, and if so, initializing the machine equipment by using the first configuration file;

and after the initialization of the machine equipment is completed, testing the preset production flow of the machine equipment by using the first configuration file and the second configuration file according to a preset production time sequence.

Optionally, the step of loading the first configuration file includes:

acquiring a second incidence relation between a trigger event CEID of the machine equipment and production process data SVID of the machine equipment, which are pre-stored in the machine equipment;

releasing the acquired second association relation;

creating a relation between the production process data identification and a trigger event CEID of the machine equipment;

creating a relation between the production process data identification and the production process data SVID of the machine equipment;

and reestablishing the first association relationship between the trigger event CEID of the machine equipment and the production process data SVID of the machine equipment.

Optionally, the step of testing the production process of the machine equipment by using the first configuration file and the second configuration file according to the production time sequence includes:

calling a first incidence relation between different trigger events of the machine equipment and different production process data in the first configuration file, so that the machine equipment performs testing according to the different production process data corresponding to the different trigger events;

calling a process formula obtaining instruction in the second configuration file, and obtaining production formula information to be detected of the machine equipment according to the process formula instruction;

when the trigger event of the machine equipment is detected to be a production formula detection event, acquiring to-be-detected generation formula information, and judging whether to modify the to-be-detected production formula information;

if the production formula information to be detected is not modified, calling the second configuration file to obtain a door opening instruction of the sending box;

and when the trigger event of the machine equipment is detected to be the reception of the first material position information event, acquiring first material position information corresponding to the first material position information event, and loading the first material position information through the second configuration file to form second material position information.

Optionally, when it is detected that the trigger event of the machine equipment is the reception of the first material position information event, the first material position information corresponding to the first material position information event is obtained, and the first material position information is loaded through the second configuration file, so that the step of forming the second material position information includes:

loading different pre-generated information instructions corresponding to the first material position information in the second configuration file according to a production time sequence;

and judging whether the different information instructions are the smallest items, if so, correspondingly modifying different production process data corresponding to the different information instructions to generate second material position information, and issuing the second material position information to the machine equipment.

Optionally, if the production formula information to be detected is judged to be modified, the second configuration file is called to obtain a material box unlocking instruction;

acquiring an editing and unlocking material box instruction generated in the second configuration file in advance;

judging whether a process data object instruction corresponding to a pre-generated edited unlocking material box is the minimum item or not, if so, modifying the object value of the process data action object into unlocking, and generating an unlocking instruction;

and issuing the unlocking instruction to the machine equipment to enable the machine equipment to remove the material box from the machine equipment.

In order to solve the above technical problem, the present application also discloses a testing apparatus for a machine tool, including:

the system comprises a first configuration module, a second configuration module and a third configuration module, wherein the first configuration module is used for loading a first configuration file, and the first configuration file stores a first incidence relation between a trigger event CEID of machine equipment and production process data SVID of the machine equipment;

the second configuration module is used for loading a second configuration file, and the second configuration file is used for loading production process data of the machine equipment;

the judging module is used for judging whether the machine equipment is connected with the machine equipment or not;

the initialization module is used for initializing the machine equipment by using the first configuration file if the judgment result of the judgment module is yes;

and the test module is used for testing the preset production flow of the machine equipment by using the first configuration file and the second configuration file according to a preset production time sequence after the initialization of the machine equipment is completed.

Optionally, the first configuration module includes:

the first acquisition module is used for acquiring a second incidence relation between a trigger event CEID of the machine equipment and production process data SVID of the machine equipment, wherein the trigger event CEID is pre-stored in the machine equipment;

a release module, configured to release the obtained second association relationship;

the first creating module is used for creating the relation between the production process data identification and the CEID of the trigger event of the machine equipment;

the second creating module is used for creating the relation between the production process data identification and the production process data SVID of the machine equipment;

the establishing module is used for reestablishing a first incidence relation between the CEID of the trigger event of the machine equipment and the SVID of the production process data of the machine equipment.

Optionally, the test module includes:

the first calling module is used for calling a first incidence relation between different trigger events of the machine equipment and different production process data in the first configuration file, so that the machine equipment is tested according to the different production process data corresponding to the different trigger events;

the second calling module is used for calling the instruction for acquiring the process formula in the second configuration file and acquiring the production formula information to be detected of the machine equipment according to the process formula instruction;

the first judgment module is used for judging whether the production formula information to be detected is modified or not when the trigger event of the machine equipment is detected as a production formula detection event;

the second calling module is further used for calling the second configuration file to acquire a door opening instruction of the feeding box if the judgment result of the judging module is that the production formula information to be detected is not modified;

and the generating module is used for acquiring first material position information corresponding to the first material position information event when detecting that the trigger event of the machine equipment is the reception of the first material position information event, and loading the first material position information through the second configuration file to form second material position information.

Optionally, the generating module includes:

the second loading module is used for loading different pre-generated information instructions corresponding to the first material position information in the second configuration file according to a production time sequence;

and the second judgment module is used for judging whether the different information instructions are the smallest items or not, if so, correspondingly modifying different production process data corresponding to the different information instructions to generate second material position information, and sending the second material position information to the machine equipment.

Optionally, if the judgment result of the first judgment module is modification, the second configuration file is called to obtain a material box unlocking instruction;

the unlocking module is used for acquiring a pre-generated material box editing and unlocking instruction in the second configuration file;

the third judgment module is used for judging whether a process data object instruction corresponding to a pre-generated and edited unlocking material box is the smallest item or not, and if so, modifying the object value of the process data action object into unlocking to generate an unlocking instruction;

and the issuing module is used for issuing the unlocking instruction to the machine equipment so that the machine equipment removes the material box from the machine equipment.

Compared with the prior art, the method has the following advantages:

in this embodiment, initialization of the device software is realized by loading the first configuration file and the second configuration file, after connection between the test software and the machine equipment is established, the machine equipment is initialized by using the first configuration file, and after initialization of the standby machine equipment is completed, a preset production flow of the machine equipment is tested by using the first configuration file and the second configuration file according to a preset production time sequence. Compared with the existing test mode, the test method has the advantages that the test personnel do not need to issue one instruction, workload of the test personnel is reduced, test software controls the issuing time sequence of the instruction, error rate during testing is reduced, the issuing of a plurality of instructions at the same time can be realized, and automatic production of the machine equipment is simulated to the maximum extent.

Of course, it is not necessary for any product to achieve all of the above-described advantages at the same time for practicing the present application.

Drawings

Fig. 1 is a flowchart of a testing method for a machine tool according to an embodiment of the present disclosure;

fig. 2 is a flowchart of a testing method for a machine tool according to an embodiment of the present disclosure;

fig. 3 is a schematic structural diagram of a testing apparatus of a machine station device according to an embodiment of the present application.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, the present application is described in further detail with reference to the accompanying drawings and the detailed description.

Referring to fig. 1, a flowchart of a testing method for a machine equipment according to an embodiment of the present application is shown, where the testing method is mainly applied to different semiconductor chip manufacturers, and different semiconductor chip manufacturers can test the machine equipment by using the testing method, and the testing method specifically includes:

step 101: and loading a first configuration file, wherein the first configuration file stores a first association relation between a trigger event CEID of the machine equipment and production process data SVID of the machine equipment.

A plurality of trigger events are defined on the equipment, the trigger events may be referred to as CEs for short, and each trigger event has an identity ID, so the trigger event of the equipment may be referred to as CEID for short.

A plurality of Status Variable data, referred to as SV data for short, are defined on the machine equipment, and each SV data has an identification ID, so that the production process data of the machine equipment can be referred to as SVID for short.

The method and the device for controlling the machine equipment manufacturer uniformly provide a first configuration file for controlling different machine equipment manufacturers, wherein the first configuration file stores a first association relation between a trigger event CEID of the machine equipment and production process data SVID of the machine equipment.

Specifically, a single name is defined for different trigger events of the equipment, and a unique ID is assigned to each name, where different equipment ID identifiers are different, but for the test software, although different equipment ID identifiers are different, the corresponding trigger events are the same, thereby implementing control of different equipment.

For example: taking a task start (cjobstart) event as an example, the test software defines the cjobstart event as ControlJobStart, the event is a CEID for the machine equipment, the identifier corresponding to the machine equipment a is 10010, the identifier corresponding to the machine equipment b is 74, and the test software can recognize that whether the identifier is 10010 or 74 corresponds to ControlJobStart through the first configuration file.

In practical application, the trigger event CEID of different equipment corresponds to the production process data SVID of different equipment, and the trigger event of one equipment corresponds to the generation data process data SVID of different equipment.

In this embodiment, step 101 includes the following sub-steps:

substep 1011: and acquiring a second incidence relation between a trigger event of the machine equipment, which is pre-stored by the machine equipment, and the production process data of the machine equipment.

Specifically, the relationship between the production process data identifier reportID and the SVID generated in advance is acquired, the relationship between the reportID and the CEID generated in advance is loaded, and a second association relationship between the CEID and the SVID is established through the reportID.

Substep 1012: and releasing the acquired second association relation.

The test software needs to be initialized before working, the reason for the software initialization is that different equipment manufacturers and different software are provided, and the state of each equipment is also different when the equipment initially enters the FAB, so the equipment needs to be initialized when the equipment accesses the test software, thereby ensuring that the state of the equipment is the state desired by the software system, and therefore the second association relationship needs to be released, and then the association relationship between the trigger event CEID of the equipment and the production process data SVID of the equipment is reestablished. Substep 1013: and creating a relation between the production process data identification and the CEID of the trigger event of the machine equipment.

Substep 1014: and creating the relation between the production process data identification and the production process data SVID of the machine equipment.

Substep 1015: and reestablishing the first association relationship between the trigger event CEID of the machine equipment and the production process data SVID of the machine equipment.

The trigger event of each machine equipment can correspond to the production process data of a plurality of machine equipment, so that when the trigger event is triggered, automatic testing can be performed according to the production process data.

And issuing the reestablished first incidence relation to the machine equipment, finishing initialization of the machine equipment when the machine equipment receives the first incidence relation, and finishing the initialization if the machine equipment does not receive the first incidence relation, wherein the initialization is abnormal and the process is finished.

Step 102: and loading a second configuration file, wherein the second configuration file is used for loading the production process data of the machine equipment.

A plurality of instructions are stored in the second configuration file, and loading of different production process data can be realized by loading the instructions in the second configuration file.

The unified management of different machine equipment by using the same software is realized through the first configuration file, and the loading of the production process data of the machine equipment is realized through the second configuration file, namely the loading of the production process data instruction to be issued is realized through the second configuration file.

Step 103: and judging whether the equipment is connected with the machine equipment, and if so, initializing the machine equipment by using the first configuration file.

If the judgment result is negative, whether the machine equipment is connected or not is continuously judged.

Step 104: and after the initialization of the machine equipment is completed, testing the preset production flow of the machine equipment by using the first configuration file and the second configuration file according to a preset production time sequence.

In this embodiment, initialization of the device software is realized by loading the first configuration file and the second configuration file, after connection between the test software and the machine equipment is established, the machine equipment is initialized by using the first configuration file, and after initialization of the standby machine equipment is completed, a preset production flow of the machine equipment is tested by using the first configuration file and the second configuration file according to a preset production time sequence. The whole test process does not need testers to issue instructions, so that the test of the automatic production of the machine equipment is realized.

Referring to fig. 2, a flowchart of a testing method for a machine equipment according to an embodiment of the present application is shown, where the testing method is mainly applied to different semiconductor chip manufacturers, and specifically includes:

step 201: and loading a first configuration file, wherein the first configuration file stores a first association relation between a trigger event CEID of the machine equipment and production process data SVID of the machine equipment.

Step 202: and loading a second configuration file, wherein the second configuration file is used for loading the production process data of the machine equipment.

Step 203: and judging whether the equipment is connected with the machine equipment, and if so, initializing the machine equipment by using the first configuration file.

Step 204: and calling a first incidence relation between different trigger events of the machine equipment and different production process data in the first configuration file, so that the machine equipment performs testing according to the different production process data corresponding to the different trigger events.

In practical application, when the trigger event of the machine equipment is detected to be a material box arrival event, the material box arrival event of the machine equipment is tested according to the first incidence relation between the material box arrival event and the production process data.

The generation process data corresponding to the cartridge arrival event can be whether the cartridge arrives or not.

And when detecting that the trigger event of the machine equipment is a receiving material box identification event, testing the receiving material box identification event of the machine equipment according to the first incidence relation between the receiving material box identification event and the production process data.

Step 205: and calling a process formula obtaining instruction in the second configuration file, and obtaining the production formula information to be detected of the machine equipment according to the process formula instruction.

In practical application, the instruction for acquiring the process recipe is stored in the second configuration file in advance, so that the generated recipe information to be detected can be acquired by calling the instruction for acquiring the process recipe in the second configuration file.

Step 206: when the trigger event of the equipment is detected to be a production recipe detection event, it is determined whether the production recipe information to be detected is modified, if not, step 207 is executed, and if so, step 211 is executed.

In a specific application, the production recipe information to be detected is compared with the production recipe information pre-stored in the machine equipment, if the production recipe information is the same as the production recipe information, the step 207 is executed if the production recipe information is not modified, and if the production recipe information is different from the production recipe information, the step 211 is executed if the production recipe information is modified.

Step 207: and calling the second configuration file to obtain a door opening instruction of the sending box.

Step 208: and when the trigger event of the machine equipment is detected to be the reception of the first material position information event, acquiring first material position information corresponding to the first material position information event, and loading the first material position information through the second configuration file to form second material position information.

In practice, step 208 may form the second location information by,

and loading different pre-generated information instructions corresponding to the first material position information in the second configuration file according to a preset production time sequence.

And judging whether the different information instructions are the smallest items, if so, correspondingly modifying different production process data object values corresponding to the different information instructions to generate second object position information, and issuing the second object position information to the machine equipment.

The following describes the process of forming the second material position information in step 208 by taking the material position information as an example, specifically as follows:

in practical application, the format of the pre-generated instruction of the second configuration file is that L5 is a single List, 5 sub-items are arranged below L5, the data identifier DATAID, the action CARRIERACTION of the process parameter, the material box identifier CARRIERID, the machine port PTN and the material port number Ln are sequentially arranged below the sub-Item Ln of L5, a sub-Item of L2 is hung below the sub-Item Ln of L5, and two sub-items are CATTRID and CATTRDATA below the sub-Item of L2.

And loading a material position information instruction generated in advance by the second configuration file according to a preset production time sequence.

And judging whether the material position information instruction is the minimum item, and if so, modifying the object value of the production process data object corresponding to the pre-generated material position information instruction into the number of wafers of the material box.

And if the material position information instruction is not the minimum Item, assigning the format of the Item to a List, and assigning the value to the child Item.

The two steps are to modify the acattiid of the child Item of l2 to < nothing > -the < nothing > in the container Attnbute Object to < Capacity >.

V CATTRDATA-primer in Camer Attnbute Value is modified to <25>, and the modified procedure is as follows:

A CATTRID＝'Capacity'-Camer Attnbute Object。

U1CATTRDATA＝'25'-Camer Attnbute Value。

and loading a wafer information instruction generated in advance by the second configuration file.

And judging whether the wafer information instruction is the minimum item or not, and if so, modifying the production process data object value corresponding to the wafer information instruction into the actual number of wafers in the material box.

The two steps are to modify < nothing > in < nothing > -Camera Attnbute Object of sub Item of l 2.

A CATTRID＝'SubstrateCount'-Camer Attnbute Object。

U1CATTRDATA＝'25'-Camer Attnbute Value。

And loading a material box state information instruction generated in advance by the second configuration file.

And judging whether the material box state information instruction is the minimum item, and if so, modifying the production process data object value corresponding to the material box state information instruction.

The two steps are to modify the A CATTRID of the child Item of l2 to < nothing > -the < nothing > in the Camera Attnbute Object to < Usage >.

A CATTRDATA-the < nothing > in the Camer Attnbute Value is modified to < PRODUCT >, and the modified procedure is as follows:

A CATTRID＝'Usage'-Camer Attnbute Object。

U1CATTRDATA＝'PRODUCT'-Camer Attnbute Value。

loading a material information instruction generated in advance by the second configuration file;

and judging whether the material information instruction is the minimum item or not, and if so, modifying the production process data object value corresponding to the material information instruction.

The two steps are to modify the a catridge of the child Item of l2 to < nothing > -the < nothing > in the container Attnbute Object to < ContentMap >.

A CATTRID＝'ContentMap'-Camer Attnbute Object。

And if the wafers exist in the material box slot positions, assigning values to A-LotID and A SubstrateID, and if the wafers do not exist, assigning the values to be empty.

And judging whether the wafer information instruction in the material box slot position is the minimum item or not, if so, modifying the production process data object value corresponding to the wafer information instruction in the material box slot position to generate second material position information, and issuing the second material position information to the machine equipment.

The two steps are to modify the A CATTRID of the child Item of l2 to < nothing > -the < nothing > in the Camera Attnbute Object to < SlotMap >.

A CATTRID＝'SlotMap'-Camer Attnbute Object。

Wafer U1 is assigned a value of 3 if the pod slot is located, and wafer U1 is assigned a value of 1 if not located.

Step 209: when the trigger event of the equipment is detected to be a material entering production equipment event, determining whether the material enters the production equipment according to the first association relationship between the material entering production equipment event and the production process data, if so, executing step 210, and if not, executing

step

211 and 213.

Step 210: and when the trigger event of the machine equipment is detected to be a production end event, judging whether the generated process data is normally ended or not, and creating an instruction for enabling the material box to exit the equipment until the production is ended and issuing the instruction to the equipment to finish the automatic material returning process.

Step 211: and calling the second configuration file to obtain a material box unlocking instruction.

Step 212: and acquiring an editing and unlocking material box instruction generated in the second configuration file in advance.

Step 213: and judging whether a process data object instruction corresponding to the edited unlocking material box generated in advance is the smallest item, if so, modifying the object value of the process data action object into unlocking, and generating an unlocking instruction.

Step 214: and issuing the unlocking instruction to the machine equipment to enable the machine equipment to remove the material box from the machine equipment.

In the embodiment, after the software is connected with the machine equipment, only the material box needs to be placed on the machine equipment, the test software can simulate the factory automation system to issue the instruction to the machine equipment, the material box is opened, the material information in the material box is verified, the instruction is automatically issued to the equipment after the verification is successful, the equipment starts to produce, the instruction for closing the material box and unlocking the material box can be automatically issued to the equipment after the production is finished, and the material box can be automatically withdrawn. In the whole process, no instruction is required to be issued by a person, and the instruction is issued by the test software according to the time sequence, so that the test on the automatic production of the equipment software is realized.

It should be noted that the foregoing method embodiments are described as a series of acts or combinations for simplicity in explanation, but it should be understood by those skilled in the art that the present application is not limited by the order of acts described, as some steps may occur in other orders or concurrently depending on the application. Further, those skilled in the art will also appreciate that the embodiments described in the specification are presently preferred and that no particular act is required to implement the invention.

Based on the description of the method embodiment, the present application further provides a corresponding apparatus embodiment to implement the content described in the method embodiment.

Referring to fig. 3, a structural diagram of a testing apparatus of a machine equipment according to an embodiment of the present application is shown, which specifically includes:

a first configuration module 301, configured to load a first configuration file, where the first configuration file stores a first association relationship between a trigger event CEID of a machine equipment and production process data SVID of the machine equipment;

a second configuration module 302, configured to load a second configuration file, where the second configuration file is used to load production process data of the machine equipment;

a judging module 303, configured to judge whether the machine equipment is connected to the machine equipment;

an initialization module 304, configured to initialize the machine equipment by using the first configuration file if the determination result of the determination module is yes;

the testing module 305 is configured to test a preset production flow of the machine equipment by using the first configuration file and the second configuration file according to a preset production time sequence after the initialization of the machine equipment is completed.

Optionally, the first configuration module includes:

the first loading module is used for acquiring a second incidence relation between a trigger event CEID of the machine equipment and production process data SVID of the machine equipment, wherein the trigger event CEID is pre-stored in the machine equipment;

the first establishing module is used for establishing the relation between the production process data identification and the trigger event of the machine equipment;

the second creating module is used for creating the relation between the production process data identification and the production process data of the machine equipment;

the establishing module is used for reestablishing the first association relationship between the trigger event CEID of the machine equipment and the production process data SID of the machine equipment.

Optionally, the test module includes:

the first judgment module is used for acquiring the generated formula information to be detected and judging whether the production formula information to be detected is modified or not when the trigger event of the machine equipment is detected to be a production formula detection event;

Optionally, the generating module includes:

In this embodiment, initialization of the device software is realized by loading the first configuration file and the second configuration file, after connection between the test software and the machine equipment is established, the machine equipment is initialized by using the first configuration file, and after initialization of the standby machine equipment is completed, a preset production flow of the machine equipment is tested by using the first configuration file and the second configuration file according to a preset production time sequence. Compared with the existing test mode, the test personnel do not need to issue one instruction, the workload of the test personnel is reduced, the issue time sequence of the instructions is controlled if the test is performed, the error rate during the test is reduced, meanwhile, the issue of a plurality of instructions at the same time can be realized, and the automatic production of the machine equipment is simulated to the maximum extent.

For the above-mentioned apparatus embodiments, since they are basically similar to the method embodiments, the description is relatively simple, and for the relevant points, reference may be made to the partial description of the illustrated method embodiments.

The embodiments in the present specification are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

As is readily imaginable to the person skilled in the art: any combination of the above embodiments is possible, and thus any combination between the above embodiments is an embodiment of the present application, but the present disclosure is not necessarily detailed herein for reasons of space.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

While the preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all alterations and modifications as fall within the scope of the application.

The above detailed description is given to a method and an apparatus for testing a machine device provided by the present application, and a specific example is applied in the present application to explain the principle and the implementation manner of the present application, and the description of the above embodiment is only used to help understand the method and the core idea of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims

1. A method for testing a machine tool, comprising:

2. The testing method of claim 1, wherein the step of loading the first configuration file comprises:

releasing the acquired second association relation;

3. The method according to claim 1, wherein the step of testing the production flow of the equipment platform using the first configuration file and the second configuration file according to the production sequence comprises:

4. The testing method according to claim 3, wherein the step of obtaining first material position information corresponding to a first material position information event when detecting that the trigger event of the machine equipment is the reception of the first material position information event, and loading the first material position information through the second configuration file to form second material position information includes:

5. The test method according to claim 3, wherein if the production recipe information to be detected is judged to be modified, the second configuration file is called to obtain a material box unlocking instruction;

6. A test apparatus for a machine tool, comprising:

7. The testing device of claim 6, wherein the first configuration module comprises:

8. The testing device of claim 6, wherein the testing module comprises:

9. The testing apparatus of claim 8, wherein the generating module comprises:

10. The testing device of claim 8, wherein if the determination result of the first determining module is modification, the second configuration file is called to obtain a material box unlocking instruction;