A standard index labeling method, labeling device and system based on human-computer interaction

By combining barcode scanners, weighing sensors, and fingerprint recognition components, automated standard indicator labeling is achieved, solving the problem of complex labeling processes in existing technologies, improving labeling efficiency, and reducing errors.

CN115900911BActive Publication Date: 2026-07-03GUIZHOU POWER GRID CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
GUIZHOU POWER GRID CO LTD
Filing Date
2022-10-24
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing standard indicator labeling methods are complex, require a large amount of data support, and rely on manual measurement, resulting in a complicated labeling process.

Method used

A standard indicator labeling method based on human-computer interaction is adopted. Automated data collection and processing are achieved through barcode scanners, weighing sensors, and fingerprint recognition components. The system classifies data into levels that meet and do not meet the standards, and labels the data through processing components.

Benefits of technology

It enables rapid and automated labeling of standard indicators, reduces manual intervention, and prevents labeling errors caused by dust contamination.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses a standard indicator labeling method, labeling device, and system based on human-computer interaction. The labeling method includes the following steps: acquiring basic material information via a barcode scanner and transmitting it to a processing element; transmitting the weight collected by a weighing sensor (used to bear the weight of the material) to the processing element; identifying the operator's identity information via a fingerprint recognition element and transmitting it to the processing element to achieve human-computer interaction; the processing element receiving information from the weighing sensor and barcode scanner and labeling it in two levels according to classification conditions; the processing element transmitting the processed information to a storage element for storage; automatically calculating the standard indicator by identifying the material's product information, weighing it using a weighing sensor, and then the processing element determining whether it meets the standard and labeling it before transmitting it to the storage element for storage, achieving the effect of quickly labeling standard indicators.
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Description

Technical Field

[0001] The present invention relates to the field of indicator labeling technology, and in particular to a standard indicator labeling method, labeling equipment and system based on human-computer interaction. Background Technology

[0002] Indicator data refers to data used for evaluation standards. It is mainly a standard indicator data specification generated to meet some internal analysis and management needs, production needs, and data processing needs. For example, after a product is produced, it is necessary to use standard indicators to determine whether the product meets the standard production standards, and then mark the product to facilitate feedback, thereby adjusting the data and effectively ensuring the qualification standards of subsequent products.

[0003] The existing evaluation and labeling methods are quite complicated. They require a lot of data to support the calculations and form the existing evaluation criteria. Then, the data is manually measured or judged to see if it meets the standard indicators, and then manually labeled using labeling equipment. This process is very complex. Summary of the Invention

[0004] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the invention.

[0005] In view of the problems existing in the standard indicator annotation methods, annotation equipment and systems based on human-computer interaction, the present invention is proposed.

[0006] Therefore, the purpose of this invention is to provide a standard indicator annotation method, annotation device and system based on human-computer interaction, the purpose of which is to: quickly annotate the standard indicators of products and indicate the operator's information based on human-computer interaction in order to facilitate subsequent statistics.

[0007] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a standard indicator labeling method based on human-computer interaction, which includes the following steps: acquiring basic material information through a barcode scanner and transmitting it to a processing element; transmitting the weight collected by a weighing sensor for bearing the weight of the material to the processing element; identifying the operator's personal information through a fingerprint recognition element and transmitting it to the processing element to achieve human-computer interaction; the processing element receiving the information from the weighing sensor and the barcode scanner and labeling it into two levels according to the classification conditions; and the processing element transmitting the processed information to a storage element for storage.

[0008] As a preferred embodiment of the standard indicator labeling method based on human-computer interaction described in this invention, the storage element is divided into two levels according to the division conditions, namely, conforming to standard S; and not conforming to standard N.

[0009] As a preferred embodiment of the standard indicator annotation method based on human-computer interaction described in this invention, the division condition for the hierarchical classification of the processing elements is: ;in, The barcode scanner is used to identify the weight standard indicators in the material information. The weight of the material supported by the weighing sensor. This refers to the material's specifications.

[0010] As a preferred embodiment of the standard indicator annotation method based on human-computer interaction described in this invention, the levels of the classification conditions include: when If it meets the standard S, then it is classified as conforming to standard S; when If it does not meet the standard N, then it is classified as not meeting the standard N; among them, The standard indicator limits for the materials described on that day, as given by the management department.

[0011] The beneficial effects of the labeling method of the present invention are as follows: After identifying the product information of the material, the processing element automatically calculates the index standard, and finally the weighing sensor weighs the material. The processing element then judges whether the material meets the standard and automatically labels it, which is then transmitted to the storage element for storage, thus achieving the effect of quickly labeling the standard index.

[0012] The second objective of this invention is to provide a standard indicator labeling device based on human-computer interaction. The purpose of this device is to enable the rapid labeling of standard indicators of products and to effectively prevent labeling errors caused by long-term dust accumulation in the workshop.

[0013] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a standard indicator labeling device based on human-computer interaction, including the labeling method described in the claims, and further including a material labeling mechanism, including a placement unit, one end of which is provided with a barcode scanner; an auxiliary labeling mechanism, which includes a load-bearing shell, an inner cavity, and a fingerprint recognition element, wherein the load-bearing shell is disposed on one side of the placement unit, and the fingerprint recognition element disposed inside it is located on the inner surface of the inner cavity; and a processing mechanism, including a processing element, a driving unit, and a blocking unit, wherein the processing element is installed inside the placement unit and cooperates with the driving unit to drive the blocking unit to move, and the blocking unit is limited in the inner cavity and located above the fingerprint recognition element.

[0014] As a preferred embodiment of the standard indicator labeling device based on human-computer interaction described in this invention, the placement unit includes a placement shell, a placement plate, and a weighing sensor; the placement plate is disposed on the outer surface of the placement shell and connected to the sensing end of the weighing sensor, and the output end of the weighing sensor is connected to the input end of the processing element.

[0015] As a preferred embodiment of the human-computer interaction-based standard indicator labeling device of the present invention, the processing mechanism further includes a storage element disposed between the load-bearing shell and the storage shell connected thereto, and the input end of the storage element is connected to the output end of the processing element; the driving unit includes a motor installed between the load-bearing shell and the storage shell, a driving assembly disposed at the output end of the motor, and a pushing assembly disposed on the outer wall of the driving assembly; the shielding unit includes a shielding plate connected to the driving end of the driving assembly, a connecting gear that is rotatable and limited inside the shielding plate, a support column installed on the shaft of the connecting gear, and a wiping plate fixed to the other end of the support column.

[0016] As a preferred embodiment of the human-computer interaction-based standard indicator labeling device of the present invention, the driving component includes a circular ring block, a screw, and a transmission gear; the screw is installed at the output end of the motor and extends into the interior of the circular ring block, with its end connected to the transmission gear, and the circular ring block and the screw mesh with each other, the transmission gear is connected below the baffle plate, and the two mesh with each other; the pushing component includes a fixing rod disposed on the outer surface of the circular ring block, and a pushing rod disposed at one end of the fixing rod; a slider disposed inside the load-bearing shell can slide in the baffle plate, and the slider meshes with the connecting gear, and the wiping end of the wiping plate is uniformly provided with bristles.

[0017] As a preferred embodiment of the standard indicator labeling device based on human-computer interaction described in this invention, it further includes a dust removal mechanism disposed in the load-bearing shell, comprising a dust inlet valve, a dust chamber, a dust outlet valve, and a dust storage cabinet; the dust inlet valve is disposed on the inner surface of the inner cavity and connected to one end of the dust chamber, the dust outlet valve connected to the other end of the dust chamber is located at the dust outlet end of the dust storage cabinet, the dust storage cabinet is slidable on the load-bearing shell, and a filter element is disposed at its outer end.

[0018] The beneficial effects of the labeling device of the present invention are: during the product loading process, the shielding unit can rotate and open to wipe the fingerprint recognition element, preventing it from being contaminated with dust generated during workshop work, making it convenient for operators to use and facilitating human-computer interaction, and it can be opened later.

[0019] Another objective of this invention is to provide a standard indicator labeling system based on human-computer interaction, the purpose of which is to enable the rapid evaluation of whether a product meets standard indicators and to implement labeling.

[0020] To address the aforementioned technical problems, this invention provides the following technical solution: a standard indicator labeling system based on human-computer interaction, comprising the labeling method and labeling device as described in the claims. Material is placed on the placement unit; material information is obtained by scanning the material with the barcode scanner and then transmitted to the processing element for processing; after sensing information, the driving unit activates to open the shielding unit, exposing the fingerprint recognition element; the operator presses the fingerprint recognition element to identify the fingerprint and obtain personal information, which is then transmitted to the processing element for processing, thus achieving human-computer interaction; the weight of the material is obtained by the weighing sensor and transmitted to the processing element for processing; the processing element integrates and processes the material information, personal information, and material weight, and transmits the data to the storage element for storage. The storage element can interact with external systems, facilitating indicator data collection.

[0021] The beneficial effects of the labeling system of the present invention are as follows: When materials are placed on the equipment, the equipment automatically weighs them, and then the processing element uses this method to quickly calculate the weight, thereby achieving automatic evaluation and labeling of standard indicators. Subsequently, personnel can read the data through the storage element, which facilitates the modification or feedback of standard indicators. Attached Figure Description

[0022] To more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein:

[0023] Figure 1 This is a schematic diagram illustrating the steps of the standard indicator annotation method based on human-computer interaction of the present invention.

[0024] Figure 2 This is a schematic diagram illustrating the transmission principle of the standard indicator annotation method and system based on human-computer interaction of the present invention.

[0025] Figure 3 This is a schematic diagram of the overall structure of the standard indicator labeling device based on human-computer interaction according to the present invention.

[0026] Figure 4 This is a schematic diagram of the overall front sectional structure of the standard indicator labeling device based on human-computer interaction according to the present invention.

[0027] Figure 5This is a top-section structural diagram of the standard indicator labeling device based on human-computer interaction according to the present invention.

[0028] Figure 6 This is a schematic diagram of the connection structure between the slider and the connecting gear in the standard indicator labeling device based on human-computer interaction according to the present invention.

[0029] Figure 7 This is a schematic diagram of the wiping plate structure in the inner cavity of the standard indicator labeling device based on human-computer interaction according to the present invention.

[0030] Figure 8 This is a schematic side sectional view of the overall structure of the standard indicator labeling device based on human-computer interaction according to the present invention.

[0031] Figure 9 This is a schematic diagram of the transmission gear and shielding plate structure of the standard indicator labeling device based on human-computer interaction according to the present invention.

[0032] Figure 10 This is a schematic diagram of the connection structure between the dust collection cabinet and the filter element in the standard indicator labeling device based on human-computer interaction according to the present invention. Detailed Implementation

[0033] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

[0034] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.

[0035] Secondly, the term "one embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that is mutually exclusive with other embodiments.

[0036] Secondly, the present invention is described in detail with reference to the schematic diagrams. When detailing the embodiments of the present invention, for ease of explanation, the cross-sectional views illustrating the device structure may be partially enlarged, not according to the usual scale. Furthermore, the schematic diagrams are merely examples and should not limit the scope of protection of the present invention. In addition, actual fabrication should include the three-dimensional spatial dimensions of length, width, and depth.

[0037] Example 1

[0038] Reference Figures 1-2This is the first embodiment of the present invention, which provides a standard indicator annotation method based on human-computer interaction. This annotation method includes the following steps:

[0039] S1: Basic information about the material is obtained by the barcode scanner 102 and transmitted to the processing element 301.

[0040] Specifically, when the material is placed under the barcode scanner 102, the barcode scanner 102 acquires information about the material to obtain basic information about the product, such as the product's serial number, material, standard specifications, and standard weight, and then transmits this data to the processing element 301.

[0041] The barcode scanner 102 can use the Deli 14951W model, and the processing element 301 can use various central processing units, i.e., CPUs, such as the Huawei Kirin 9000, depending on the situation.

[0042] S2: The weight collected by the load cell 101c for bearing the material is transmitted to the processing element 301 based on the weight it bears.

[0043] Specifically, when the material is placed on the load-bearing surface of the weighing sensor 101c, the weighing sensor 101c can weigh the material, convert the mass signal into a measurable electrical signal output, and transmit the measured weight data to the processing element 301 for processing.

[0044] The 101c load cell can be a pressure-type load cell of the 101cF1822 series.

[0045] S3: The fingerprint recognition element 203 identifies the operator's personal information and transmits it to the processing element 301 to realize human-computer interaction.

[0046] Specifically, after completing the above two steps, the operator places the finger with the stored fingerprint on the fingerprint recognition element 203. At this time, the fingerprint recognition element 203 can recognize the operator's task information, such as including but not limited to name and employee number and completed standard indicator information, and then transmit the information to the processing element 301 for authentication.

[0047] The fingerprint recognition element 203 can be used with a fingerprint collector of model ZWY-060.

[0048] S4: The information received by the processing element 301 from the weighing sensor 101c and the barcode scanner 102 is divided into two levels and labeled according to the classification conditions.

[0049] Specifically, at this point, the processing element 301 has already collected the material data obtained by the barcode scanner 102 and the weighing sensor 101c, and then... The material grades are classified in this way to check whether the standard indicators are met, and the grades are divided into S (compliant) and N (non-compliant). To enable the barcode scanner 102 to identify the weight standard indicators in the material information, The weight of the material supported by the load cell 101c. This refers to the material's specifications.

[0050] For example, the standard indicator limit for the day 50kg is S, 50kg is N. The information scanned by barcode scanner 102 indicates that the material weight standard set for the day is 80% or that it is set by itself. However, the material weight data obtained by weighing sensor 101c is 60kg. Therefore, 60kg * 80% equals 48kg. If the weight is less than 50 kg, the material is labeled as N; otherwise, if the weight is ≥50 kg, it is labeled as S.

[0051] S5: The processing element 301 transmits the processed information to the storage element 304 for storage.

[0052] Specifically, after the processing element 301 marks the standard indicators S or N, it transmits the operator's information identified by the fingerprint recognition element 203 to the storage element 304 for storage, so that subsequent staff can check and verify and provide feedback, thus completing the entire process.

[0053] The storage element 304 can be used with Western Digital SN750 for storage.

[0054] Furthermore, this method can not only be used in this field, but also to label express delivery inspection indicators. For example, it can be used to detect whether the weight of the express delivery meets the standard for the shipping fee. If it is less than or equal to the standard, the shipping fee indicator is used; if it is greater than the standard, a higher shipping fee indicator is used.

[0055] Example 2

[0056] Reference Figures 3-10 This is the second embodiment of the present invention. This embodiment differs from the first embodiment in that it is a standard indicator labeling device based on human-computer interaction. This labeling device includes a material labeling mechanism 100, an auxiliary labeling mechanism 200, a processing mechanism 300, and a dust storage mechanism 400.

[0057] Specifically, the material labeling mechanism 100 includes a storage unit 101, with a barcode scanner 102 installed at one end of the storage unit 101. To facilitate the acquisition and reading of material information, the barcode scanner 102 is placed at one end of the storage unit 101, either above or outside the storage unit 101, as long as it can scan the barcode. In this case, the barcode scanner 102 can scan the data of the storage unit 101.

[0058] The auxiliary labeling mechanism 200 includes a load-bearing shell 201, an inner cavity 202, and a fingerprint recognition element 203. The load-bearing shell 201 is disposed on one side of the storage unit 101, and the fingerprint recognition element 203 disposed inside it is located on the inner surface of the inner cavity 202. After reading the material information, the operator's fingerprint can be scanned by pressing the operator's finger on the fingerprint recognition element 203, thereby obtaining the operator's personal information and task information.

[0059] The processing mechanism 300 includes a processing element 301, a driving unit 302, and a blocking unit 303. The processing element 301 is installed inside the storage unit 101 and works with the driving unit 302 to move the blocking unit 303. The blocking unit 303 is limited in the inner cavity 202 and located above the fingerprint recognition element 203. The processing element 301 can process the information obtained by the fingerprint recognition element 203, the storage unit 101, and the barcode scanner 102, and simultaneously activate the driving unit 302 to operate, driving the blocking unit 303 to no longer block the fingerprint recognition element 203, and simultaneously cleaning the fingerprint recognition element 203.

[0060] The dust collection mechanism 400 is installed in the load-bearing shell 201 and includes a dust inlet valve 401, a dust chamber 402, a dust outlet valve 403, and a dust collection cabinet 404. The dust inlet valve 401 is installed on the inner surface of the inner cavity 202 and connected to one end of the dust chamber 402. The dust outlet valve 403, connected to the other end of the dust chamber 402, is located at the dust outlet end of the dust collection cabinet 404. The dust collection cabinet 404 can slide on the load-bearing shell 201, and a filter element 404a is provided at its outer end. The dust to be cleaned will remain in the inner cavity 202. The pushing component 302c causes the dust to be continuously sucked into the dust chamber 402 through the dust inlet valve 401 and then discharged from the dust outlet valve 403 into the dust collection cabinet 404. The dust collection cabinet 404 can be removed by sliding to clean the dust accumulated in the dust collection cabinet 404. At the same time, the filter element 404a can also discharge gas and prevent dust from passing through.

[0061] Furthermore, the storage unit 101 includes a storage housing 101a, a storage plate 101b, and a weighing sensor 101c. The storage plate 101b is disposed on the outer surface of the storage housing 101a and connected to the sensing end of the weighing sensor 101c, and the output end of the weighing sensor 101c is connected to the input end of the processing element 301.

[0062] Specifically, when the material is placed on the shelf 101b on the shelf housing 101a, the shelf 101b supports the entire material, thus providing complete support. The weight data of the material can be acquired by the weighing sensor 101c and transmitted to the processing element 301 for processing.

[0063] Furthermore, the processing mechanism 300 also includes a storage element 304, which is disposed between the load-bearing shell 201 and the storage shell 101a connected thereto. The input end of the storage element 304 is connected to the output end of the processing element 301. The drive unit 302 includes a motor 302a installed between the load-bearing shell 201 and the storage shell 101a, a drive assembly 302b disposed at the output end of the motor 302a, and a pushing assembly 302c disposed on the outer wall of the drive assembly 302b. The shielding unit 303 includes a shielding plate 303a connected to the drive end of the drive assembly 302b, a connecting gear 303b that is rotatable and limited inside the shielding plate 303a, a support column 303c installed on the axis of the connecting gear 303b, and a wiping plate 303d fixed to the other end of the support column 303c.

[0064] Specifically, when the processing element 301 senses information, it drives the motor 302a, which in turn drives the drive component 302b to operate. The drive component 302b then moves the blocking plate 303a of the blocking unit 303. At this time, the blocking plate 303a moves under the limit action, allowing the wiping plate 303d, which is connected to the connecting gear 303b through the support column 303c, to wipe the fingerprint recognition element 203. At the same time, it no longer blocks the fingerprint recognition element 203, protecting it while reminding the operator to recognize and collect the fingerprint. The collected data is then transmitted to the processing element 301 for processing. The processing element 301 integrates the data and transmits it to the storage element 304 for storage, making it easy for subsequent personnel to view. Conversely, after recognition is completed, the motor 302a reverses again, and according to the above principle, it covers and protects the fingerprint recognition element 203 again.

[0065] Furthermore, the drive assembly 302b includes an annular block 302b-1, a screw 302b-2, and a transmission gear 302b-3. The screw 302b-2 is installed at the output end of the motor 302a and extends into the interior of the annular block 302b-1, with its end connected to the transmission gear 302b-3. The annular block 302b-1 and the screw 302b-2 mesh with each other. The transmission gear 302b-3 is connected to the lower part of the baffle plate 303a, and the two mesh with each other. The pushing assembly 302c includes a fixing rod 302c-1 disposed on the outer surface of the annular block 302b-1, and a pushing rod 302c-2 disposed at one end of the fixing rod 302c-1. The slider 201a disposed inside the load-bearing shell 201 can slide in the baffle plate 303a, and the slider 201a meshes with the connecting gear 303b. The wiping end of the wiping plate 303d is uniformly provided with bristles.

[0066] Specifically, the motor 302a drives the screw 302b-2. When the screw 302b-2 rotates, it first drives the transmission gear 302b-3 to rotate, which in turn drives the baffle 303a to move. The baffle 303a moves under the limiting action of the slider 201a. At this time, the slider 201a also meshes with the connecting gear 303b inside it, thereby driving the connecting gear 303b to rotate. The connecting gear 303b then drives the support column 303c to rotate, which in turn drives the wiping plate 303d to rotate. The wiping plate 303d is evenly provided with bristles, which can effectively wipe the fingerprint recognition element 203 by rotating the bristles, preventing the dust on it from becoming seriously contaminated due to the humidity of the workshop.

[0067] Preferably, during the rotation of the screw 302b-2, it also engages with the teeth on the annular block 302b-1. At this time, the annular block 302b-1, due to its installation method, can only translate. Therefore, the annular block 302b-1 will not be rotated by the screw 302b-2, but will only translate. This allows the annular block 302b-1 to move the fixed rod 302c-1, which in turn moves the push rod 302c-2 connected to one end, driving it to move. The push rod 302c-2 moves and compresses the gas in the dust chamber 402, creating pressure. Under vacuum, this pressure causes the gas to be discharged quickly through the dust outlet valve 403, creating a negative pressure. Under this negative pressure, the dust inlet valve 401 draws the dust cleaned from the inner cavity 202 into the dust chamber 402, and then discharges it from the dust outlet valve 403 into the dust storage cabinet 404 under pressure. Excess gas is discharged through the filter element 404a, and the dust is blocked and collected inside the dust storage cabinet 404 for easy disassembly and cleaning.

[0068] Example 3

[0069] Reference Figures 1-10 This is the third embodiment of the present invention, which differs from the second embodiment in that it is a standard indicator labeling system based on human-computer interaction.

[0070] Specifically, the material is first placed on the shelf 101b, and the weight of the material is identified by the weighing sensor 101c in the shelf housing 101a. The basic information of the material is then scanned by the barcode scanner 102. The two sets of data from the barcode scanner 102 and the weighing sensor 101c are then transmitted to the processing element 301. At this time, the processing element 301 opens the shielding unit 303 through the drive unit 302 to expose the fingerprint recognition element 203. The operator can then place their finger on the fingerprint recognition element 203 to identify the operator's basic information, which is then transmitted to the processing element 301, completing the collection of a complete set of data.

[0071] Furthermore, when the processing element 301 collects three sets of data from the fingerprint recognition element 203, the barcode scanner 102, and the weighing sensor 101c, it can then establish... , and The formula is used to calculate and form standard indicators that meet standard S and do not meet standard N. These indicators are marked on the personnel information identified by the fingerprint recognition element 203. By integrating these data, they are transmitted to the storage element 304 for storage, so that the staff can perform identification processing later.

[0072] It is important to note that the constructions and arrangements of this application shown in several different exemplary embodiments are merely illustrative. Although only a few embodiments are described in detail in this disclosure, those who consult this disclosure will readily understand that many modifications are possible (e.g., changes in the size, dimensions, structure, shape, and proportions of various elements, as well as parameter values ​​(e.g., temperature, pressure, etc.), mounting arrangements, use of materials, color, orientation, etc.) without substantially departing from the novel teachings and advantages of the subject matter described in this application). For example, an element shown as integrally formed may be composed of multiple parts or elements, the position of elements may be inverted or otherwise altered, and the nature or number or position of discrete elements may be changed or altered. Therefore, all such modifications are intended to be included within the scope of the invention. The order or sequence of any process or method steps may be changed or rearranged according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structure described herein that performs the function, and not only structurally equivalent but also equivalent in structure. Other substitutions, modifications, alterations, and omissions may be made in the design, operation, and arrangement of the exemplary embodiments without departing from the scope of the invention. Therefore, the invention is not limited to the specific embodiments, but extends to various modifications that still fall within the scope of the appended claims. Furthermore, for the purpose of providing a concise description of exemplary embodiments, not all features of actual embodiments (i.e., those features not relevant to the currently considered best mode for carrying out the invention, or those features not relevant to implementing the invention) may be omitted.

[0073] It should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all such modifications or substitutions should be covered within the scope of the claims of the present invention.

Claims

1. A standard index labeling device based on human-computer interaction, characterized in that: include, Basic information about the material is obtained by a barcode scanner (102) and transmitted to the processing element (301). The weight collected by the load cell (101c) for bearing the material is transmitted to the processing element (301) based on the weight it bears. The fingerprint recognition element (203) identifies the operator's personal information and transmits it to the processing element (301) to realize human-computer interaction; The information received by the processing element (301) from the weighing sensor (101c) and the barcode scanner (102) is divided into two levels and labeled according to the classification criteria. The processing element (301) transmits the processed information to the storage element (304) for storage; The material labeling mechanism (100) includes a storage unit (101), one end of which is provided with a barcode scanner (102). The auxiliary labeling mechanism (200) includes a load-bearing shell (201), an inner cavity (202) and a fingerprint recognition element (203). The load-bearing shell (201) is disposed on one side of the storage unit (101), and the fingerprint recognition element (203) disposed inside it is located on the inner surface of the inner cavity (202). The processing mechanism (300) includes a processing element (301), a driving unit (302), and a blocking unit (303). The processing element (301) is installed inside the storage unit (101) and works with the driving unit (302) to move the blocking unit (303). The blocking unit (303) is limited in the inner cavity (202) and located above the fingerprint recognition element (203). The drive unit (302) includes a motor (302a) installed between the load-bearing shell (201) and the storage shell (101a), a drive assembly (302b) disposed at the output end of the motor (302a), and a push assembly (302c) disposed on the outer wall of the drive assembly (302b). The shielding unit (303) includes a shielding plate (303a) connected to the driving end of the driving assembly (302b), a connecting gear (303b) that is rotatable and limited inside the shielding plate (303a), a support column (303c) installed on the axis of the connecting gear (303b), and a wiping plate (303d) fixed to the other end of the support column (303c). It also includes a dust storage mechanism (400), which is disposed in the load-bearing shell (201), and includes a dust inlet valve (401), a dust chamber (402), a dust outlet valve (403) and a dust storage cabinet (404). The dust inlet valve (401) is disposed on the inner surface of the inner cavity (202) and connected to one end of the dust chamber (402). The dust outlet valve (403) connected to the other end of the dust chamber (402) is located at the dust outlet end of the dust storage cabinet (404). The dust storage cabinet (404) can slide on the load-bearing shell (201), and a filter element (404a) is provided at its outer end.

2. The human-machine interaction based standard indicator labeling device according to claim 1, characterized in that: The storage element (304) is divided into two levels according to the classification criteria, which respectively include: Meets standard S; It does not conform to standard N.

3. The human-machine interaction based standard indicator labeling device according to claim 1 or 2, characterized in that: The classification criteria for the processing element (301) are as follows: ; wherein, to identify a weight standard in the material information for the barcode scanner (102), to weigh the material for the load cell (101c), to index the material.

4. The human-machine interaction based standard indicator labeling device according to claim 3, characterized in that: The levels of the classification criteria include, When then the partition is classified as conforming to the standard S; When then the classification is not in accordance with the standard N; in, The standard indicator limits for the materials described on that day, as given by the management department.

5. The standard indicator labeling device based on human-computer interaction according to claim 4, characterized in that: The storage unit (101) includes a storage housing (101a), a storage plate (101b), and a weighing sensor (101c). The storage plate (101b) is disposed on the outer surface of the storage housing (101a) and connected to the sensing end of the weighing sensor (101c), and the output end of the weighing sensor (101c) is connected to the input end of the processing element (301).

6. The standard indicator labeling device based on human-computer interaction according to claim 5, characterized in that: The processing mechanism (300) further includes a storage element (304) disposed between the load-bearing shell (201) and the storage shell (101a) connected thereto, and the input end of the storage element (304) is connected to the output end of the processing element (301).

7. The standard indicator labeling device based on human-computer interaction according to claim 6, characterized in that: The drive assembly (302b) includes an annular block (302b-1), a screw (302b-2), and a transmission gear (302b-3). The screw (302b-2) is installed at the output end of the motor (302a) and extends into the interior of the annular block (302b-1), with its end connected to the transmission gear (302b-3). The annular block (302b-1) and the screw (302b-2) mesh with each other, and the transmission gear (302b-3) is connected below the baffle plate (303a), with the two meshing with each other. The pushing assembly (302c) includes a fixing rod (302c-1) disposed on the outer surface of the annular block (302b-1), and a pushing rod (302c-2) disposed at one end of the fixing rod (302c-1). The slider (201a) inside the load-bearing shell (201) can slide in the baffle plate (303a), and the slider (201a) meshes with the connecting gear (303b). The wiping end of the wiping plate (303d) is uniformly provided with bristles.

8. A standard indicator annotation system based on human-computer interaction, comprising the annotation device described in any one of claims 5 to 7, characterized in that: The material is placed on the storage unit (101), and the material information is obtained by scanning the material with the barcode scanner (102) and then transmitted to the processing element (301) for processing; After the driving unit (302) senses the information, it is activated to drive the blocking unit (303) to open and expose the fingerprint recognition element (203). The operator presses the fingerprint recognition element (203) to recognize the fingerprint and obtain the person's information, which is then transmitted to the processing element (301) for processing, thus realizing human-computer interaction. The weight of the material is obtained by the weighing sensor (101c) and then transmitted to the processing element (301) for processing; The processing element (301) integrates and processes the material information, personnel information, and material weight, and transmits them to the storage element (304) for storage. The storage element (304) can interact with external systems to facilitate the collection of indicator data.