CN116205574A

CN116205574A - Product warehouse-in inspection method and device, product inspection equipment and readable storage medium

Info

Publication number: CN116205574A
Application number: CN202310168568.3A
Authority: CN
Inventors: 请求不公布姓名
Original assignee: Huizhou Haikui Information Technology Co ltd
Current assignee: Huizhou Haikui Information Technology Co ltd
Priority date: 2023-02-23
Filing date: 2023-02-23
Publication date: 2023-06-02

Abstract

The application provides a product warehouse-in inspection method and device, product inspection equipment and a readable storage medium, and relates to the technical field of product material management. According to the method and the device, the target identity of the product to be inspected, which needs to be put in storage, is obtained, the pre-stored design scheme matched with the product to be inspected is searched according to the target identity, the to-be-measured list of the product to be inspected is determined according to the pre-stored design scheme, then product measurement guiding operation is carried out according to the to-be-measured list, after the actual product parameter values fed back by different detection measuring tools aiming at the to-be-detected parts of the product to be inspected are obtained, the inspection result list of the product to be inspected is automatically generated according to the obtained actual product parameter values, so that the product inspection efficiency, the product inspection accuracy and the inspection accuracy stability are effectively improved, the inspection manpower loss and the inspection personnel requirements are effectively reduced, and the source tracing operation of the product inspection process is conveniently realized.

Description

Product warehouse-in inspection method and device, product inspection equipment and readable storage medium

Technical Field

The application relates to the technical field of product material management, in particular to a product warehouse-in inspection method and device, product inspection equipment and a readable storage medium.

Background

With the continuous development of science and technology, the application of manufacturing industry production management technology is more and more extensive, and a plurality of manufacturing industry workshops put forward higher material management demands for produced products, wherein the warehouse-in inspection operation for product parts is a necessary operation content for realizing the product material management effect in the current manufacturing industry workshops.

It is noted that, in the conventional product warehousing inspection scheme, the inspection personnel usually performs warehousing inspection operation on the product parts manually, which causes the specific inspection accuracy condition of the conventional product warehousing inspection scheme to change along with the change of the inspection skill grasping degree of the inspection personnel and/or the inspection concentration degree of the inspection personnel, so that the problem of low product inspection efficiency, poor product inspection accuracy, poor inspection accuracy stability, high inspection personnel requirement and high inspection manpower loss exists in the whole product warehousing inspection scheme, and meanwhile, the inspection manpower cost is greatly consumed.

Disclosure of Invention

In view of this, an object of the present application is to provide a product warehouse-in inspection method and apparatus, a product inspection device and a readable storage medium, which can effectively guide an inspector to realize a product parameter collection effect, and utilize a data transmission technology to communicate an electronic device to realize an automatic product parameter inspection effect with respect to the collected actual product parameter data, so as to effectively improve product inspection efficiency, product inspection accuracy and inspection accuracy stability, effectively reduce inspection manpower loss and inspector requirements, and simultaneously facilitate realization of traceability operation of a product inspection process.

In order to achieve the above purpose, the technical solution adopted in the embodiment of the present application is as follows:

in a first aspect, the present application provides a method of product warehouse entry inspection, the inspection method comprising:

acquiring a target identity of a product to be inspected which needs to be put in storage;

searching a pre-stored design scheme matched with the product to be checked according to the target identity;

determining a to-be-measured list of the to-be-inspected product according to the pre-stored design scheme, wherein the to-be-measured list comprises point location information and/or recommended measuring tool types of all to-be-inspected parts corresponding to the to-be-inspected product;

performing product measurement guiding operation according to the list to be measured;

acquiring actual product parameter values fed back by different detection measuring tools aiming at a part to be detected;

and generating a checking result list of the product to be checked according to the respective actual product parameter values of all the parts to be checked of the product to be checked.

In an alternative embodiment, the test method further comprises:

marking the inspection result list as a good inspection list or a suspected non-good inspection list according to the product inspection data recorded by the inspection result list;

when the inspection result list is marked as a suspected non-good inspection list, the inspection result list is sent to at least one review terminal device for product review;

Obtaining a product review result fed back by the at least one review terminal device;

re-labeling the inspection result list as a good inspection list or a non-good inspection list according to the respective review result content of all the product review results;

prompting a warehouse-in confirmation message for the product to be inspected when the inspection result list is marked as a good inspection list, or prompting a product repair message or a product return message for the product to be inspected when the inspection result list is marked as a non-good inspection list.

In an optional implementation manner, the step of marking the inspection result list as a good inspection list or a suspected non-good inspection list according to the product inspection data recorded in the inspection result list includes:

detecting whether each part to be detected of the product to be detected is qualified or not according to the product detection data recorded by the detection result list;

marking the inspection result list as a good inspection list under the condition that all parts to be detected are detected to be qualified;

and marking the inspection result list as a suspected defective inspection list under the condition that at least one part to be detected is unqualified.

In an alternative embodiment, the test method further comprises:

marking the inspection result list as a suspected good inspection list or a suspected non-good inspection list according to the product inspection data recorded by the inspection result list;

acquiring a manual judgment and inspection result aiming at the product to be inspected;

marking the inspection result list as a good product inspection list from a suspected good product inspection list under the condition that the manual judgment inspection result and the inspection result list both indicate that the product to be inspected belongs to a suspected good product;

when the manual judgment test result and/or the test result list indicate that the product to be tested belongs to a suspected non-good product, the test result list is sent to at least one evaluation terminal device for product evaluation;

In an optional implementation manner, the step of marking the inspection result list as a suspected good inspection list or a suspected non-good inspection list according to the product inspection data recorded in the inspection result list includes:

marking the inspection result list as a suspected good inspection list under the condition that all the parts to be detected are detected to be qualified;

In an alternative embodiment, the step of re-labeling the inspection result list as a good inspection list or a non-good inspection list according to the respective review result content of all the product review results includes:

detecting whether each product review result indicates that the product to be inspected is qualified or not according to the review result content of each product review result;

under the condition that each product review result is detected to indicate that the product to be inspected is qualified, the inspection result list is re-marked as a good inspection list;

And under the condition that at least one product review result is detected to indicate that the product to be inspected is unqualified, the inspection result list is re-marked as a non-good inspection list.

In an alternative embodiment, the step of determining the to-be-measured list of the to-be-inspected product according to the pre-stored design scheme includes:

searching a target inspection list corresponding to the target identity in the stored historical non-good inspection list;

determining an unqualified product position corresponding to a product to be inspected in the searched target inspection list, and constructing the list to be measured corresponding to the unqualified product position according to a pre-stored design scheme of the product to be inspected.

In an alternative embodiment, the test method further comprises:

generating corresponding product inspection tasks according to the receiving data of the products to be stored;

and carrying out product inspection screening indication operation according to the product inspection task.

In a second aspect, the present application provides a product warehouse entry inspection device, the inspection device comprising:

the product identification acquisition module is used for acquiring a target identification of a product to be inspected which needs to be put in storage;

the design scheme searching module is used for searching a pre-stored design scheme matched with the product to be checked according to the target identity;

The measurement list making module is used for determining a to-be-measured list of the to-be-inspected product according to the pre-stored design scheme, wherein the to-be-measured list comprises point location information and/or recommended measuring tool types of all to-be-inspected parts corresponding to the to-be-inspected product;

the inventory measurement guiding module is used for conducting product measurement guiding operation according to the inventory to be measured;

the product parameter acquisition module is used for acquiring actual product parameter values fed back by different detection measuring tools aiming at the part to be detected;

and the inspection list generation module is used for generating an inspection result list of the product to be inspected according to the respective actual product parameter values of all the parts to be inspected of the product to be inspected.

In an alternative embodiment, the test device further comprises;

the result list labeling module is used for labeling the inspection result list as a good product inspection list or a suspected non-good product inspection list according to the product inspection data recorded by the inspection result list;

the product review transmitting module is used for transmitting the inspection result list to at least one review terminal device for product review when the inspection result list is marked as a suspected non-good inspection list;

The review result acquisition module is used for acquiring a product review result fed back by the at least one review terminal device;

the list re-marking module is used for re-marking the inspection result list as a good inspection list or a non-good inspection list according to the respective review result content of all the product review results;

and the product message prompting module is used for prompting a warehouse-in confirmation message for the product to be inspected when the inspection result list is marked as a good product inspection list, or prompting a product repair message or a product return message for the product to be inspected when the inspection result list is marked as a non-good product inspection list.

In an alternative embodiment, the test device further comprises;

the result list labeling module is used for labeling the inspection result list as a suspected good inspection list or a suspected non-good inspection list according to the product inspection data recorded by the inspection result list;

the manual judgment acquisition module is used for acquiring a manual judgment inspection result aiming at the product to be inspected;

the result list labeling module is further configured to label the inspection result list as a good product inspection list from a suspected good product inspection list when the manual evaluation inspection result and the inspection result list both indicate that the product to be inspected belongs to a suspected good product;

The product review sending module is used for sending the inspection result list to at least one review terminal device for product review under the condition that the manual evaluation inspection result and/or the inspection result list indicate that the product to be inspected belongs to suspected non-good products;

In an alternative embodiment, the test device further comprises;

the inspection task generating module is used for generating corresponding product inspection tasks according to the receiving data of the products to be put in storage;

and the product screening indication module is used for carrying out product inspection screening indication operation according to the product inspection task.

In a third aspect, the present application provides a product inspection apparatus comprising a processor and a memory, the memory storing a computer program executable by the processor, the processor being executable to implement the product warehousing inspection method of any one of the preceding embodiments.

In a fourth aspect, the present application provides a readable storage medium having stored thereon a computer program which, when executed by a processor, implements the product warehousing inspection method of any one of the foregoing embodiments.

In this case, the beneficial effects of the embodiments of the present application include the following:

according to the method, the target identity of the product to be inspected, which is required to be put in storage, is obtained, the pre-stored design scheme matched with the product to be inspected is searched according to the target identity, the to-be-measured list of the product to be inspected is determined according to the pre-stored design scheme, then the product measurement guiding operation is carried out according to the to-be-measured list, after the actual product parameter values fed back by different detection measuring tools aiming at the to-be-inspected parts of the product to be inspected are obtained, the inspection result list of the product to be inspected is automatically generated according to the respective actual product parameter values of all the to-be-inspected parts of the product to be inspected, so that inspection personnel can be effectively guided to realize the product parameter acquisition effect, and the automatic product parameter inspection effect is realized aiming at the acquired actual product parameter values by utilizing the data transmission technology, so that the product inspection efficiency, the product inspection precision and the inspection precision stability are effectively improved, the inspection manpower loss and the inspection personnel requirement are effectively reduced, and the source operation of the product inspection process is conveniently realized.

In order to make the above objects, features and advantages of the present application more comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered limiting the scope, and that other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is an interactive schematic diagram of a product inspection device, a review terminal device and a detection gauge according to an embodiment of the present application;

fig. 2 is a schematic flow chart of a product warehouse entry inspection method according to an embodiment of the present application;

FIG. 3 is a second flow chart of a method for inspecting product warehouse entry according to an embodiment of the present disclosure;

FIG. 4 is a third flow chart of a method for inspecting product warehouse entry according to an embodiment of the present disclosure;

FIG. 5 is a flow chart of a method for inspecting warehouse entry of products according to an embodiment of the present disclosure;

fig. 6 is one of the schematic diagrams of the product warehouse entry inspection device according to the embodiment of the present application;

FIG. 7 is a second schematic diagram of a product warehouse entry inspection device according to an embodiment of the present disclosure;

fig. 8 is a third schematic diagram of a product warehouse entry inspection device according to an embodiment of the present disclosure.

Icon: 10-product inspection equipment; 11-a server; 12-checking end equipment; 30-review terminal equipment; 40-measuring tool; 100-a product warehouse-in inspection device; 110-a product identification acquisition module; 120-a design solution searching module; 130-a measurement list making module; 140-list measurement guidance module; 150-a product parameter acquisition module; 160-a checklist generation module; 170-a result list labeling module; 180-a product review sending module; 190-a review result acquisition module; 210-a manifest remarking module; 220-a product message prompt module; 230-a manual judgment acquisition module; 240-a verification task generation module; 250-product screening indication module.

Detailed Description

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, which are generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, as provided in the accompanying drawings, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present application, it should be understood that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

Some embodiments of the present application are described in detail below with reference to the accompanying drawings. The embodiments described below and features of the embodiments may be combined with each other without conflict.

Referring to fig. 1, fig. 1 is an interaction schematic diagram of a product inspection apparatus 10, a review end apparatus 30 and a detection gauge 40 according to an embodiment of the present disclosure. In this embodiment of the present application, the product inspection device 10 may be in communication connection with a plurality of detection gauges 40 with different gauge types, where each detection gauge 40 may feed back, through a network, product parameter information collected by itself to the inspection end device 12 when collecting product parameter information matched with a corresponding gauge type, so as to effectively avoid manual data input operation of an inspector in a product inspection process, reduce inspection manpower loss and inspector requirements, and ensure accuracy of measured data. The gauge type of the gauge 40 may be, but is not limited to, an inner diameter gauge, an outer diameter gauge, a depth gauge, a length gauge, a height gauge, a hardness gauge, a smoothness gauge, etc.

The measuring tool 40 corresponding to the inside diameter measuring tool may be an inside diameter micrometer with a built-in wireless communication module, or may be an inside diameter micrometer externally connected with wireless communication equipment; the measuring tool 40 corresponding to the external diameter measuring tool may be an external diameter micrometer with a built-in wireless communication module, or may be an external diameter micrometer externally connected with wireless communication equipment; the measuring tool 40 corresponding to the depth measuring tool may be a digital display depth gauge or an electronic depth gauge with a built-in wireless communication module, or may be a digital display depth gauge or an electronic depth gauge externally connected with wireless communication equipment; the measuring tool 40 corresponding to the length measuring tool may be a caliper with a built-in wireless communication module, or may be a caliper externally connected with a wireless communication device; the measuring tool 40 corresponding to the height detecting tool may be an electronic height gauge with a built-in wireless communication module, or may be an electronic height gauge externally connected with a wireless communication device; the measuring tool 40 corresponding to the hardness measuring tool may be a hardness measuring instrument with a built-in wireless communication module, or may be a hardness measuring instrument externally connected with a wireless communication device; the measuring tool 40 corresponding to the smoothness measuring tool may be a friction coefficient measuring instrument with a built-in wireless communication module, or may be a friction coefficient measuring instrument externally connected to a wireless communication device.

In this embodiment of the present application, when the inspector determines that a certain product to be put in storage belongs to a product to be inspected, the product inspection device 10 may generate a corresponding matched list to be measured for the product to be inspected, where the list to be measured includes respective point location information and/or recommended measuring tool types corresponding to all current positions to be inspected of the product to be inspected, and then perform product measurement guiding operation based on the list to be measured, so that the inspector calls measuring tools 40 matched with the measuring tool types for each current position to be inspected of the product to be inspected to perform product parameter detection processing according to the guiding action of the product inspection device 10, thereby effectively guiding the inspector to implement product parameter collection effect, reducing inspection manpower loss and inspection personnel requirements, and improving product parameter collection efficiency. The point location information is used for representing specific position information of the corresponding to-be-detected part at the whole product to be detected, and the recommended measuring tool type is used for representing a measuring tool type required when the corresponding to-be-detected part is measured.

After the inspection staff performs measurement operation on the to-be-detected part responsible for measurement through the measurement tool 40, the measurement tool 40 feeds back the product parameter information acquired by the inspection tool 40 to the product inspection equipment 10, the product inspection equipment 10 performs parameter information matching with the product parameter information of the corresponding to-be-detected part based on the product parameter standard range corresponding to different to-be-detected parts, so as to generate an inspection result list of the to-be-inspected product, which comprises the parameter matching results corresponding to all to-be-detected parts, thereby the server 11 effectively realizes automatic product parameter inspection effect aiming at the acquired product parameter actual information, further reduces inspection manpower loss and inspection staff requirements, effectively improves the product inspection efficiency, product inspection precision and inspection precision stability of the to-be-inspected product, and simultaneously facilitates the follow-up realization of product inspection process source operation through the obtained inspection result list. The product parameter standard range is used for representing a distribution range of expected product parameter values configured at a product design stage corresponding to the part to be detected.

In this embodiment of the present application, the product inspection device 10 may be communicatively connected to at least one evaluation end device 30, and configured to, when it is determined by itself that the product to be inspected belongs to a suspected non-good product based on the obtained inspection result list of the product to be inspected, send the inspection result list of the product to be inspected to the at least one evaluation end device 30, and, according to a set evaluation criterion (for example, whether a part of product parameters corresponding to the product to be inspected can be accepted in a yield, whether a product item corresponding to the product to be inspected can achieve a desired effect, whether a product item corresponding to the product to be inspected is urgent, etc.), output a corresponding product evaluation result for the product to be inspected at the corresponding evaluation end device 30, and then, feedback the obtained product evaluation result to the server 11 by each evaluation end device 30, and automatically determine, by the server 11, whether the product to be inspected is qualified or not based on all the obtained product evaluation results, whether the product to be inspected needs to be classified under a good product category, and whether the product to be inspected needs to be classified under a good product category, thereby achieving an effective product evaluation condition. The review terminal device 30 is a terminal device held by a review person, and the terminal device may be, but is not limited to, a tablet computer, a smart phone, a handheld terminal, and the like.

Optionally, in this embodiment of the present application, in the process of executing the product measurement guiding operation, the product inspection device 10 may display, to an inspector, respective product parameter standard ranges of all to-be-detected positions of the product to be inspected, so that the inspector manually performs parameter qualification status assessment on each to-be-detected position at the product inspection device 10, so that the product inspection device 10 can combine a good product assessment result of itself for the product to be inspected and a manual assessment result made by the inspector, and cooperate with the at least one review terminal device 30 to implement a product quality status assessment effect with higher accuracy in the process of executing the product quality status assessment operation.

In the present embodiment, the product inspection apparatus 10 may be a separately formed computer apparatus; the product inspection device 10 may also be a combination of a plurality of computing devices in communication with each other, where the plurality of computing devices cooperate to perform the specific functions of the product inspection device 10 described above.

In one implementation of the present example, the product testing device 10 may be combined with a testing end device 12 by a server 11, wherein the server 11 is communicatively connected to the at least one review end device 30, the testing end device 12 is communicatively connected to the plurality of gauges 40, and the server 11 is communicatively connected to the testing end device 12.

The product to be inspected may be determined at the inspection end device 12 by an inspector, the server 11 generates a corresponding list to be measured for the product to be inspected, and sends the list to be measured to the inspection end device 12 for product measurement guiding processing, at this time, the inspection end device 12 acquires product parameter information acquired by each of the plurality of inspection gauges 40, and feeds back the acquired product parameter information to the server 11 to generate a corresponding inspection result list, and then the server 11 may perform information interaction with the at least one evaluation end device 30 based on the obtained inspection result list, so as to implement product quality assessment operation. The inspection end device 12 is a terminal device held by an inspector, and the terminal device may be, but is not limited to, a tablet computer, a smart phone, a handheld terminal, and the like.

In the process of realizing the product quality condition assessment operation, the inspector can also manually evaluate the parameter qualification condition of the product to be inspected at the inspection end device 12, and the inspection end device 12 uploads the manual evaluation result to the server 11, so that the server 11 can combine the product quality condition assessment result and the manual evaluation result, and the product quality condition assessment effect with higher precision can be realized by matching with the at least one evaluation end device 30.

It will be appreciated that the block diagram shown in fig. 1 is merely an interactive schematic diagram of a product inspection device 10, wherein the product inspection device 10 may also include more or fewer components than shown in fig. 1, or have a different configuration than shown in fig. 1. The components shown in fig. 1 may be implemented in hardware, software, or a combination thereof.

In this application, in order to ensure that the product inspection device 10 can guide the inspector to achieve the product parameter collection effect, and achieve the automatic product parameter inspection effect according to the collected actual product parameter information, so as to effectively improve the product inspection efficiency, the product inspection accuracy and the inspection accuracy stability, and effectively reduce the inspection manpower loss and the inspector requirement, the embodiment of the application provides a product warehouse-in inspection method applied to the product inspection device 10 to achieve the aforementioned purposes. The product warehouse-in inspection method provided by the application is explained in detail below.

Referring to fig. 2, fig. 2 is a flow chart of a product warehouse-in inspection method according to an embodiment of the present application. In the embodiment of the present application, the product warehouse entry inspection method may include steps S310 to S315.

Step S310, obtaining the target identity of the product to be inspected, which needs to be put in storage.

In this embodiment, the product inspection device 10 may scan the identification code of the product to be inspected through a scanner to obtain the target identification of the product to be inspected; the product inspection device 10 may also acquire the target identity of the product to be inspected uploaded by an inspector via a network.

In one implementation manner of this embodiment, the product inspection device 10 includes an inspection end device 12 and a server 11 that are in communication with each other, an inspector can scan the identity code of the product to be inspected through a scanner of the inspection end device 12 to obtain the target identity of the product to be inspected, and the inspection end device 12 sends the target identity to the server 11 to inform the server 11 that the product parameter inspection is required to be performed on the product to be inspected currently, so as to determine whether to allow the inspected product to be put in storage as a good product.

Step S311, searching a pre-stored design scheme matched with the product to be checked according to the target identity.

In this embodiment, the memory of the product inspection apparatus 10 may store product designs of various products, where the product designs may be expressed by using a three-dimensional product design model and/or a two-dimensional product design drawing, where the three-dimensional product design model and/or the two-dimensional product design drawing may be labeled with point location information and product parameter standard ranges of a plurality of detectable product locations where the preparation requirements exist, so that the server 11 generates a corresponding to-be-measured list for the product to be inspected.

After obtaining the target identity of the product to be inspected, the product inspection device 10 screens out a target design scheme matched with the target identity from multiple product design schemes stored in the product inspection device, and then obtains a pre-stored design scheme matched with the product to be inspected.

In one implementation of this embodiment, if the product inspection device 10 includes an inspection end device 12 and a server 11 that are in communication with each other, the product designs of the products are stored in the memory at the server 11, and the server 11 searches for a pre-stored design that matches the product to be inspected.

Step S312, determining a to-be-measured list of the to-be-inspected product according to a pre-stored design scheme, wherein the to-be-measured list comprises point location information and/or recommended measuring tool types of all to-be-inspected parts corresponding to the to-be-inspected product.

In this embodiment, the product inspection apparatus 10 may obtain a to-be-measured list currently corresponding to the to-be-inspected product by performing information capturing on the searched pre-stored design scheme, where the to-be-measured list includes point location information and/or recommended measuring tool types of all to-be-inspected parts corresponding to the to-be-inspected product.

In one implementation manner of this embodiment, all the detected product positions marked in the searched pre-stored design scheme can be directly used as the current position to be detected of the product to be detected, so as to ensure that the to-be-measured bill can realize the comprehensive detection effect in the subsequent product parameter detection operation process.

In another implementation manner of this embodiment, in order to effectively save the product parameter checking time for the product to be checked and avoid meaningless product parameter checking operations, the step of determining the to-be-measured list of the product to be checked according to the pre-stored design scheme may include:

under the condition that a target inspection list is found, determining an unqualified product position corresponding to a product to be inspected in the found target inspection list, and constructing a list to be measured corresponding to the unqualified product position according to a pre-stored design scheme of the product to be inspected;

under the condition that the target inspection list is not found, the point location information of each detectable product part is directly extracted from a pre-stored design scheme matched with the target identity to construct the list to be measured.

The historical non-good inspection list is used for indicating a recorded inspection result list of the products judged to be non-good products, and the historical non-good inspection list has at least one product part, wherein the actual value of the historical product parameter of the at least one product part does not meet the corresponding product parameter standard range, i.e. the product part belongs to a non-qualified product part with failed parameter matching at the position of the historical non-good inspection list.

When a corresponding target inspection list is found in a historical non-good inspection list according to the target identity of the product to be inspected, namely, the product to be inspected is substantially subjected to product parameter inspection, but the product to be inspected is judged to be non-good in the process of product parameter inspection, at the moment, product parameter inspection can be carried out again only on the unqualified product part with failed parameter matching in the target inspection list, so that the product parameter inspection time of the product to be inspected, which is judged to be non-good, is effectively saved, meaningless product parameter inspection operation is avoided, and at the moment, the to-be-measured list can only comprise the point position information and/or recommended measuring tool type of each of the unqualified product parts of the product to be inspected.

In one implementation of this embodiment, if the product inspection device 10 includes an inspection end device 12 and a server 11 that communicate with each other, the server 11 may execute the specific step details of the step S312.

Step S313, performing product measurement guiding operation according to the list to be measured.

In this embodiment, when the product inspection apparatus 10 generates a corresponding to-be-measured list for the product to be inspected, the inspection personnel may be guided to call the measuring tool 40 with the matching measuring tool type at each physical point of the product to be inspected to perform the product parameter collection operation by displaying the information of the to-be-measured list.

In one implementation of this embodiment, if the product inspection device 10 includes an inspection end device 12 and a server 11 that are in communication with each other, the server 11 may send a generated to-be-measured list to the inspection end device 12 that uploads the target identity through a network, so as to inform the inspection end device 12 to instruct a corresponding inspector to perform a product parameter measurement operation on the to-be-inspected product according to the to-be-measured list by using a suitable measuring tool 40.

If the to-be-measured list includes the respective point location information of all to-be-detected positions corresponding to the to-be-detected product, after receiving the to-be-measured list from the server 11, the inspection end device 12 may perform information display to an inspector after performing point location labeling on the three-dimensional product design model and/or the two-dimensional product design drawing of the to-be-detected product based on the respective point location information of all to-be-detected positions of the to-be-detected product recorded by the to-be-measured list, so as to guide the inspector to invoke a suitable detection measuring tool 40 at a corresponding physical point location on the to-be-detected product to perform product parameter acquisition operation, and obtain a product detection parameter value fed back by the detection measuring tool 40.

The inspection end device 12 may also acquire current actual product surface data of the product to be inspected through a scanner, and construct an actual three-dimensional product model of the product to be inspected based on the actual product surface data, so as to display information to an inspector after marking the point positions of each part to be inspected on the actual three-dimensional product model according to the respective point position information of all the parts to be inspected of the product to be inspected recorded by the list to be measured when the list to be measured is obtained.

When the inspection end device 12 displays the point location information of the to-be-inspected portion of the to-be-inspected product, arrow prompts can be formed at the point location marking position of the to-be-inspected portion so as to guide the inspector to measure the product parameters at the physical point location corresponding to the to-be-inspected product. In addition, if the to-be-measured list further includes the recommended measuring tool types corresponding to all to-be-measured positions of the product to be inspected, the recommended measuring tool types of the to-be-measured positions can be prompted in a text manner at the point marking positions corresponding to the to-be-measured positions, so that the inspector can select the appropriate measuring tool 40 according to the prompted recommended measuring tool types to implement the product parameter measurement operation at the to-be-measured positions.

In this embodiment, the to-be-measured list may further include respective product parameter standard ranges of all to-be-detected positions corresponding to the to-be-detected product, so that the inspector determines upper and lower limits of the actually allowable product parameters at the to-be-detected positions according to the prompted product parameter standard ranges.

Step S314, obtaining actual product parameter values fed back by different detection measuring tools aiming at the part to be detected.

In this embodiment, after the inspector measures the actual product parameter information of the to-be-inspected portion of the product to be inspected by calling the inspection gauge 40, the inspection gauge 40 will feed back the corresponding product inspection parameter values to the product inspection device 10, so that the product inspection device 10 obtains the actual product parameter values of different to-be-inspected portions of the product to be inspected.

In one implementation manner of this embodiment, if the product inspection device 10 includes an inspection end device 12 and a server 11 that are in communication with each other, after the inspection end device 12 obtains the product inspection parameter values collected by each inspection gauge 40 for the corresponding portion to be inspected, an inspector may collect, for each inspection gauge 40, multiple sets of product inspection parameter values obtained for the corresponding portion to be inspected, perform manual data correction, and remove jitter data in the corrected product inspection parameter values by the inspection end device 12, so as to ensure that the actual product parameter values corresponding to the portion to be inspected are stable and effective.

After obtaining the respective actual product parameter values of all the to-be-detected parts of the to-be-detected product related to the to-be-detected list, the inspection end device 12 may upload the respective actual product parameter values of all the to-be-detected parts of the to-be-detected product to the server 11 through a network, and the server 11 may implement an automatic product parameter inspection effect with respect to the collected product parameter information.

Step S315, generating a checking result list of the product to be checked according to the respective actual product parameter values of all the parts to be checked of the product to be checked.

In this embodiment, the product inspection apparatus 10 may generate the inspection result list of the product to be inspected according to the respective parameter matching results of all the parts to be inspected by performing parameter matching on the actual product parameter value of each part to be inspected of the product to be inspected and the corresponding product parameter standard range.

The product inspection data are used for representing parameter matching results of actual product parameter values of corresponding to the to-be-inspected parts and a product parameter standard range, each parameter matching result is recorded with actual product parameter values of the corresponding to-be-inspected parts, the product parameter standard range and standard range coincidence results, and the standard range coincidence results can be that the actual product parameter values of the corresponding to-be-inspected parts accord with the corresponding product parameter standard range, or that the actual product parameter values of the corresponding to-be-inspected parts do not accord with the corresponding product parameter standard range.

If the standard range accords with the standard range, the actual product parameter value of the corresponding part to be detected accords with the standard range of the corresponding product parameter, the parameter of the part to be detected is successfully matched, the product parameter of the part to be detected is suspected to accord with the warehousing standard, and the detected part is qualified; if the standard range accords with the actual product parameter value corresponding to the part to be detected and does not accord with the standard range of the corresponding product parameter, the parameter matching of the part to be detected fails, the product parameter of the part to be detected is suspected to not accord with the warehousing standard, and the part to be detected is not qualified.

In one implementation of this embodiment, if the product inspection device 10 includes an inspection end device 12 and a server 11 that communicate with each other, the server 11 may execute the specific step details of step S315 described above.

From this, this application accessible carries out above-mentioned step S310 ~ step S315, ensures that product inspection equipment 10 can guide the inspection personnel mutually supporting and realize the product parameter acquisition effect to realize automatic product parameter inspection effect to the product parameter actual information who gathers, with effectively promoting product inspection efficiency, product inspection precision and inspection precision stability, and effectively reduce inspection manpower loss and inspection personnel' S requirement, be convenient for follow-up realization product inspection process operation of tracing to the source through the inspection result list of the product that waits to inspect that obtains simultaneously.

Optionally, referring to fig. 3, fig. 3 is a second flowchart of a product warehouse-in checking method according to an embodiment of the present application. In this embodiment, compared to the product warehouse entry inspection method shown in fig. 2, the product warehouse entry inspection method shown in fig. 3 may further include steps S320 to S324 to implement the automated product quality assessment effect of the product inspection apparatus 10.

Step S320, marking the inspection result list as a good inspection list or a suspected non-good inspection list according to the product inspection data recorded in the inspection result list.

In this embodiment, the step of marking the inspection result list as the good inspection list or the suspected non-good inspection list according to the product inspection data recorded in the inspection result list may include:

If the product inspection device 10 includes an inspection end device 12 and a server 11 that are in communication with each other, when the server 11 detects that all the to-be-inspected positions of the product to be inspected are in a parameter matching success state, that is, the actual product parameter values of all the to-be-inspected positions of the product to be inspected conform to the corresponding product parameter standard range, the product to be inspected substantially conforms to the warehouse-in standard, at this time, the product to be inspected may be regarded as a good product, and the inspection result list of the product to be inspected may be marked as a good product inspection list, or when at least one to-be-inspected position is detected to be in a parameter matching failure state, that is, the actual product parameter value of at least one to-be-inspected position of the product to be inspected does not conform to the corresponding product parameter standard range, the product to be inspected may be suspected to be non-conforming to the warehouse-in standard, at this time, the product to be regarded as a suspected non-good product, and the inspection result list of the product to be marked as a suspected non-good product inspection list.

And S321, when the inspection result list is marked as a suspected non-good inspection list, transmitting the inspection result list to at least one review terminal device for product review.

Step S322, obtaining a product review result fed back by at least one review terminal device.

In this embodiment, after the reviewer completes the product review operation on the inspection result list of the product to be inspected at the corresponding review terminal device 30, the corresponding product review result is fed back to the product inspection device 10 through the network, and the product inspection device 10 (or the server 11 included in the product inspection device 10) performs information reading and identification on all obtained product review results to determine whether all product review results indicate that the product to be inspected is qualified.

And step S323, re-labeling the inspection result list as a good inspection list or a non-good inspection list according to the respective review result contents of all the product review results.

In this embodiment, the step of re-labeling the inspection result list as the good inspection list or the non-good inspection list according to the respective review result contents of all the product review results may include:

When the product inspection device 10 (or the server 11 included in the product inspection device 10) determines that all the product review results indicate that the product to be inspected is qualified, the product to be inspected can be regarded as meeting the warehousing standard, the product to be inspected can be used as a good product, and the inspection result list of the product to be inspected can be re-marked as a good product inspection list.

When the product inspection device 10 (or the server 11 included in the product inspection device 10) determines that at least one product review result indicates that the product to be inspected is not qualified, the product to be inspected can be regarded as not meeting the warehouse-in standard, the product to be inspected can be used as a non-good product, and the inspection result list of the product to be inspected can be re-marked as a non-good product inspection list.

In step S324, when the inspection result list is marked as a good inspection list, a warehouse-in confirmation message is prompted for the product to be inspected, or when the inspection result list is marked as a non-good inspection list, a product repair message or a product return message is prompted for the product to be inspected.

In this embodiment, the memory of the product inspection apparatus 10 (or the server 11 included in the product inspection apparatus 10) may be integrated with an MES (Manufacturing Execution System, manufacturing enterprise production process execution system) work order system and an SAP (enterprise resource management software system) management system for a product production shop, and each large process of the product production process is integrated by the MES work order system, and the production operation condition of the whole product production shop is integrated by the SAP management system.

The product inspection device 10 (or the server 11 included in the product inspection device 10) may prompt the SAP system for a warehouse entry confirmation message to indicate that the product to be inspected is available for direct shipment when the inspection result list is labeled as a good inspection list; when the inspection result list is marked as a non-good inspection list, the product inspection device 10 (or the server 11 included in the product inspection device 10) can prompt the SAP system with a product repair message or a product return message to indicate that the inspected product is not receivable in a warehouse, and needs repair processing or direct return processing.

Thus, the present application can realize the automated product quality assessment effect of the product inspection apparatus 10 by executing the above steps S320 to S324.

Optionally, referring to fig. 4, fig. 4 is a third flow chart of the product warehouse-in checking method according to the embodiment of the present application. In this embodiment of the present application, compared to the product warehouse entry inspection method shown in fig. 2, the product warehouse entry inspection method shown in fig. 4 may further include steps S330 to S336, so as to ensure that an inspector can cooperate with the product inspection apparatus 10 to effectively realize a product quality assessment effect with higher accuracy.

Step S330, marking the inspection result list as a suspected good inspection list or a suspected non-good inspection list according to the product inspection data recorded in the inspection result list.

In this embodiment, the step of labeling the inspection result list as the suspected good inspection list or the suspected non-good inspection list according to the product inspection data recorded in the inspection result list may include:

If the product inspection device 10 includes an inspection end device 12 and a server 11 that are in communication with each other, when the server 11 detects that all the to-be-inspected positions of the product to be inspected are in a parameter matching success state, that is, the actual product parameter values of all the to-be-inspected positions of the product to be inspected conform to the corresponding product parameter standard range, the product to be inspected is suspected to conform to the warehousing standard, at this time, the product to be inspected is regarded as a suspected good product, the inspection result list of the product to be inspected is marked as a suspected good product inspection list, or when at least one to-be-inspected position is detected to be in a parameter matching failure state, that is, the actual product parameter value of at least one to-be-inspected position of the product to be inspected does not conform to the corresponding product parameter standard range, at this time, the product to be inspected is regarded as a suspected good product, and the inspection result list of the product to be inspected is marked as a suspected good product inspection list.

Step S331, obtaining a manual judgment inspection result aiming at a product to be inspected.

In this embodiment, the product inspection device 10 (or the inspection end device 12 included in the product inspection device 10) may display the respective product parameter standard ranges of all the to-be-inspected positions of the product to be inspected to an inspector, and the inspector may compare the actual product parameter values of the same to-be-inspected position with the corresponding product parameter standard ranges by itself to determine whether the actual product parameter values of the to-be-inspected positions are within the corresponding product parameter standard ranges, and then input the corresponding manual evaluation results to the product inspection device 10 (or the inspection end device 12 included in the product inspection device 10) to obtain the manual evaluation inspection results of the product to be inspected.

If all the manual evaluation results of the parts to be detected respectively show that the actual product parameter values of the corresponding parts to be detected are in the standard range of the corresponding product parameters, the manual labeling inspection result shows that the product to be inspected is suspected to be good; and if the manual evaluation result of at least one part to be detected shows that the actual product parameter value of the corresponding part to be detected is not in the corresponding product parameter standard range, the manual labeling inspection result shows that the product to be inspected is suspected to be a defective product.

If the inspection end device 12 obtains a manual evaluation and inspection of the product to be inspected by an inspector, the manual evaluation and inspection of the product to be inspected is sent to the server 11 through a network to perform a product quality evaluation operation.

In step S332, when the manual evaluation test result and the test result list both indicate that the product to be tested belongs to the suspected good, the test result list is marked as a good test list from the suspected good test list.

In this embodiment, when the product inspection apparatus 10 (or the server 11 included in the product inspection apparatus 10) determines that the manual evaluation inspection result and the inspection result list both indicate that the product to be inspected belongs to a suspected good product, that is, the product to be inspected substantially meets the warehousing standard, the product to be inspected is regarded as a good product, and the inspection result list of the product to be inspected is marked as a good product inspection list.

Step S333, when the manual judgment of the inspection result and/or the inspection result list indicate that the product to be inspected belongs to the suspected non-good product, the inspection result list is sent to at least one review terminal device for product review.

Step S334, obtaining a product review result fed back by at least one review terminal device.

And step S335, re-labeling the inspection result list as a good inspection list or a non-good inspection list according to the respective review result contents of all the product review results.

In step S336, when the inspection result list is marked as a good inspection list, a warehouse-in confirmation message is prompted for the product to be inspected, or when the inspection result list is marked as a non-good inspection list, a product repair message or a product return message is prompted for the product to be inspected.

In this embodiment, when the inspection result list is marked as a good inspection list, the product inspection device 10 (or the server 11 included in the product inspection device 10) may prompt the SAP system for a warehouse entry confirmation message to indicate that the product to be inspected is available for direct shipment; when the inspection result list is marked as a non-good inspection list, the product inspection device 10 (or the server 11 included in the product inspection device 10) can prompt the SAP system with a product repair message or a product return message to indicate that the inspected product is not receivable in a warehouse, and needs to be repaired or returned directly.

Therefore, the present application can ensure that the inspector can cooperate with the product inspection device 10 to effectively realize the product quality assessment effect with higher accuracy by executing the steps S330 to S336.

Optionally, referring to fig. 5, fig. 5 is a flow chart of a product warehouse-in inspection method according to an embodiment of the present application. In the embodiment of the present application, compared to the product warehouse entry inspection method shown in fig. 2, 3 or 4, the product warehouse entry inspection method shown in fig. 5 may further include steps S340 to S341.

Step S340, corresponding product inspection tasks are generated according to the receiving data of the products to be put in storage.

In this embodiment, the receiving data may include a product type, a material attribute (e.g., machine tool, outsourcing, raw material, etc.), a product inspection parameter type (e.g., material, process requirement, surface treatment, appearance, size, etc.), and a product importance level of the corresponding product to be put in storage. The product inspection device 10 (or the server 11 included in the product inspection device 10) may generate corresponding product inspection tasks for characterizing product sampling inspection types and product sampling inspection numbers for the products to be stored according to the receiving data of the products to be stored, so as to ensure that the inspector can intuitively know the real-time status of the materials of the products to be stored, which are required to perform the storage inspection operation currently, through the product inspection tasks.

Step S341, performing product inspection screening indication operation according to the product inspection task.

In this embodiment, the product inspection apparatus 10 may instruct an inspector to screen out products to be inspected from products to be put in storage by displaying information on the product inspection task.

In one implementation manner of this embodiment, if the server 11 included in the product inspection device 10 generates the product inspection task, the server 11 may send the generated product inspection task to the inspection end device 12 included in the product inspection device 10, and the inspection end device 12 displays information on the product inspection task to instruct an inspector to screen out a product to be inspected from products to be received and put in storage.

Therefore, the automatic screening function of the products to be tested can be realized by executing the steps S340 to S341.

In order to ensure that the product inspection apparatus 10 can effectively perform the product warehousing inspection method, the present application stores software function modules and computer programs included in the product warehousing inspection device in a memory of the product inspection apparatus 10, and executes the software function modules and computer programs included in the product warehousing inspection device by a processor of the product inspection apparatus 10 to implement the product warehousing inspection method. It will be appreciated that, if the product inspection device 10 is formed by combining a plurality of computing devices, the product warehouse entry inspection device may be divided into part of the content of the product warehouse entry inspection device integrated at different computing devices, and the product warehouse entry inspection method may be implemented through data interaction between the part of the content of the product warehouse entry inspection device. The specific constitution of the product warehouse-in inspection device applied to the above-described product inspection apparatus 10 provided in the present application will be described correspondingly.

Referring to fig. 6, fig. 6 is a schematic diagram of a product warehouse entry inspection device 100 according to an embodiment of the present disclosure. In this embodiment, the product warehouse entry inspection device 100 may include a product identifier obtaining module 110, a design searching module 120, a measurement list making module 130, a list measurement guiding module 140, a product parameter obtaining module 150, and an inspection list generating module 160.

The product identifier obtaining module 110 is configured to obtain a target identifier of a product to be inspected that needs to be put in storage.

And the design scheme searching module 120 is configured to search a pre-stored design scheme matched with the product to be checked according to the target identity.

And the measurement list making module 130 is configured to determine a to-be-measured list of the to-be-inspected product according to the pre-stored design scheme, where the to-be-measured list includes point location information and/or recommended measurement tool types of all to-be-inspected positions corresponding to the to-be-inspected product.

And the inventory measurement guiding module 140 is used for conducting product measurement guiding operation according to the inventory to be measured.

The product parameter obtaining module 150 is configured to obtain actual product parameter values fed back by different detection gauges for the to-be-detected positions.

And the inspection list generating module 160 is configured to generate an inspection result list of the product to be inspected according to respective actual product parameter values of all the parts to be inspected of the product to be inspected.

Optionally, referring to fig. 7, fig. 7 is a second schematic diagram of a product warehouse entry inspection device 100 according to an embodiment of the present disclosure. In this embodiment, compared to the product warehousing inspection device 100 shown in fig. 6, the product warehousing inspection device 100 may further include a result list labeling module 170, a product review transmitting module 180, a review result obtaining module 190, a list re-labeling module 210, and a product message prompting module 220.

The result list labeling module 170 is configured to label the inspection result list as a good inspection list or a suspected non-good inspection list according to the product inspection data recorded in the inspection result list.

And the product review transmitting module 180 is configured to transmit the inspection result list to at least one review terminal device for product review when the inspection result list is marked as a suspected non-good inspection list.

And the review result acquisition module 190 is configured to acquire a product review result fed back by the at least one review end device.

The manifest remarking module 210 is configured to remark the inspection result manifest as a good product inspection manifest or a non-good product inspection manifest according to the review result contents of all the product review results.

And the product message prompting module 220 is configured to prompt a warehouse-in confirmation message for the product to be inspected when the inspection result list is marked as a good inspection list, or prompt a product repair message or a product return message for the product to be inspected when the inspection result list is marked as a non-good inspection list.

In this embodiment, compared to the product warehousing inspection device 100 shown in fig. 6, the product warehousing inspection device 100 may further include a result list labeling module 170, a product review transmitting module 180, a review result obtaining module 190, a list re-labeling module 210, a product message prompting module 220, and a manual review obtaining module 230.

The result list labeling module 170 is configured to label the inspection result list as a suspected good inspection list or a suspected bad inspection list according to the product inspection data recorded in the inspection result list.

And the manual judgment acquisition module 230 is used for acquiring a manual judgment inspection result for the product to be inspected.

The result list labeling module 170 is further configured to label the inspection result list as a good product inspection list from a suspected good product inspection list when the manual evaluation inspection result and the inspection result list both indicate that the product to be inspected belongs to a suspected good product.

And the product review sending module 180 is configured to send the inspection result list to at least one review terminal device for product review when the manual review inspection result and/or the inspection result list indicate that the product to be inspected belongs to a suspected non-good product.

Optionally, referring to fig. 8, fig. 8 is a third schematic diagram of a product warehouse entry inspection device 100 according to an embodiment of the present disclosure. In this embodiment, the product warehouse entry inspection device 100 may further include an inspection task generating module 240 and a product screening indication module 250.

The inspection task generating module 240 is configured to generate a corresponding product inspection task according to the receiving data of the product to be warehoused.

And the product screening indication module 250 is used for performing product inspection screening indication operation according to the product inspection task.

It should be noted that, the basic principle and the technical effects of the product warehouse-in inspection device 100 provided in the embodiment of the present application are the same as the product warehouse-in inspection method described above. For a brief description, reference is made to the description of the method for checking the warehouse entry of products described above, where this section of the embodiment is not mentioned.

In this application, an embodiment of the present application further provides a storage medium storing a computer program, where the storage medium includes a plurality of machine instructions to cause a processor of an electronic device to execute the computer program to implement any one of the product warehousing inspection methods described above. Wherein the computer program may be implemented in the form of software functional modules.

In summary, in the method and apparatus for product warehouse entry inspection, product inspection device and readable storage medium provided in the embodiments of the present application, the target identity of a product to be inspected to be warehouse-in is obtained, and a pre-stored design scheme matched with the product to be inspected is searched according to the target identity, so as to determine a list to be measured of the product to be inspected according to the pre-stored design scheme, then product measurement guiding operation is performed according to the list to be measured, after obtaining actual product parameter values fed back by different inspection gauges for the to-be-inspected portions of the product to be inspected, an inspection result list of the product to be inspected is automatically generated according to respective actual product parameter values of all to-be-inspected portions of the product to be inspected, thereby effectively guiding inspection personnel to achieve product parameter collection effects, and utilizing data transmission technology to deliver electronic equipment to achieve automated product parameter inspection effects for the collected actual product parameter values, so as to effectively improve product inspection efficiency, product inspection precision and inspection precision stability, effectively reduce inspection manpower loss and inspection personnel requirements, and facilitate realization of traceable operations of product inspection processes.

The foregoing is merely various embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present application, and the changes and substitutions are intended to be covered in the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims

1. A method for inspecting a product for warehouse entry, the method comprising:

2. The method of testing of claim 1, further comprising:

3. The inspection method according to claim 2, wherein the step of labeling the inspection result list as a good inspection list or a suspected bad inspection list based on the product inspection data recorded in the inspection result list comprises:

4. The method of testing of claim 1, further comprising:

5. The inspection method according to claim 4, wherein the step of labeling the inspection result list as a suspected good inspection list or a suspected bad inspection list based on the product inspection data recorded in the inspection result list comprises:

6. The method according to any one of claims 2 to 5, wherein the step of re-labeling the inspection result list as a good inspection list or a non-good inspection list according to the respective review result contents of all the product review results comprises:

7. The method according to any one of claims 2-5, wherein the step of determining a list of products to be tested from the pre-stored design scheme comprises:

8. The method of testing of claim 1, further comprising:

9. A product warehouse entry inspection device, the inspection device comprising:

10. A product inspection apparatus comprising a processor and a memory, the memory storing a computer program executable by the processor, the processor being executable to implement the product warehousing inspection method of any one of claims 1-8.

11. A readable storage medium having stored thereon a computer program, which, when executed by a processor, implements the product warehousing verification method according to any one of claims 1-8.