CN110246553B - Wireless radio frequency management equipment and method for automatic printing and labeling machine - Google Patents

Abstract

The wireless radio frequency management equipment and method of the automatic printing and labeling machine of the present invention relate to an equipment and method for automatic management of blood bags. The purpose is to provide a radio frequency management device and method for an automatic printing and labeling machine that can achieve complete, fast and full-process traceability management and high data processing accuracy. The wireless radio frequency management device of the automatic printing and labeling machine of the present invention is applied to a biological sample container with a first label, the biological sample container has first data, the first label stores the first data and has a first identification code, specifically including A server, a first component, a second component, a third component and a transport unit. The transport unit is provided with a first working area, a second working area and a third working area connected in sequence.

Description

Radio frequency management equipment of automatic printing labeling machine and method thereof

Technical Field

The invention relates to the technical field of blood bag management, in particular to a wireless radio frequency management device and a method thereof for an automatic printing labeling machine for automatically managing blood bags.

Background

In a typical hospital or research institute, medical personnel typically access a patient's blood through a blood bag or tube while processing the blood sample, and enter patient-related data into a computer system to print an identification code or manually write on a label of the blood bag or tube.

In order to improve the management efficiency and ensure the correctness and traceability of blood bag information, a related management mode by utilizing a wireless radio frequency tag is developed. However, the foregoing approach only addresses data identification of a single blood bag, and in fact, the blood bag ultimately needs to be accessed for storage in a blood bank, removed until needed for use, and provides retrospective management of subsequent use and verification, which is frequent and not error-tolerant. The existing technical means are difficult to meet the requirements of efficient and full-flow management. In view of this, there is an urgent need in the market for a wireless radio frequency management device for an automatic printing and labeling machine to solve the drawbacks of the prior art.

Disclosure of Invention

The invention aims to solve the technical problem of providing wireless radio frequency management equipment and a method thereof, which can achieve the automatic printing labeling machine with complete and rapid tracing management and full flow and high data processing accuracy.

The invention relates to a wireless radio frequency management device of an automatic printing labeling machine, which is applied to a biological sample container with a first label, wherein the biological sample container is provided with first data, the first label stores the first data and is provided with a first identification code, and the wireless radio frequency management device comprises

The server is used for providing a storage unit for storing the first data;

the conveying unit is used for conveying the biological sample container, and is provided with a first working area, a second working area and a third working area, wherein the biological sample container sequentially passes through the first working area, the second working area and the third working area;

the first component is connected with the server and used for scanning a first identification code on the biological sample container in the first working area and acquiring corresponding first data from the storage unit according to the first identification code;

the second component is connected with the server and is used for receiving the first data scanned in the first component, printing second data with a second identification code on the label surface of a second label and writing the second data into the second label, and attaching the second label to a biological sample container positioned in a second working area, wherein the second data provided by the second label comprises two forms of visualization and digitalization; and

and the third component is connected with the server and used for scanning the second identification code of the visual second data and reading the electronic second data, and when the server confirms that the second data is consistent with the first data, the management operation before warehousing of the biological sample container is completed.

The invention relates to a wireless radio frequency management device of an automatic printing labeling machine, wherein the first identification code and the second identification code are one-dimensional bar codes or two-dimensional bar codes.

The invention relates to a wireless radio frequency management device of an automatic printing labeling machine, wherein the size of a second label is not smaller than that of a first label.

The wireless radio frequency management device of the automatic printing labeling machine comprises at least one of a biological sample container type, a biological sample container capacity, a biological sample container number, a sampled identity, a biological sample type, a sampling time, a sampling place, a sampling date or a sampled identity.

The invention discloses a wireless radio frequency management device of an automatic printing labeling machine, wherein the second label comprises a wireless radio frequency identification chip, and the wireless radio frequency identification chip is used for processing and storing second data.

The invention relates to a wireless radio frequency management device of an automatic printing labeling machine, wherein a wireless radio frequency identification chip uses a frequency band of ultrahigh frequency.

The invention relates to a wireless radio frequency management device of an automatic printing labeling machine, wherein the conveying unit is a single-section or multi-section conveying belt.

The invention discloses a wireless radio frequency management method of an automatic printing labeling machine, which is applied to a biological sample container with a first label, wherein the biological sample container is provided with first data, the first label stores the first data and is provided with a first identification code, and the wireless radio frequency management method comprises the following steps:

s1, scanning the first identification code to obtain first data stored in a servo end in advance;

s2, printing the content of second data related to the first data on a second label to form visible second data;

s3, writing the content of the second data into a wireless radio frequency identification chip of the second tag to form digitized second data;

s4, attaching a second label to the biological sample container to replace the first label;

s5, scanning visible second data and reading digital second data, comparing the first data with the second data, if the first data and the second data do not accord, performing step S6, and if the first data and the second data accord, performing step S7;

s6, sending a notification, and returning to the step S1;

s7, outputting a biological sample container with a second label; and

s8, ending the step.

After step S7, the biological sample container with the second label is sent to the corresponding position of the blood bank.

In the wireless radio frequency management method of the automatic printing labeling machine, in the step S4, the first label is covered by the second label, so that the first label is replaced by the second label.

The wireless radio frequency management equipment of the automatic printing and labeling machine is different from the prior art in that the wireless radio frequency management equipment of the automatic printing and labeling machine can be used for providing management of blood bags, and a brief flow is that when blood is donated, for example, one-dimensional code labels are attached to the blood bags to confirm various data of blood sources and the data are stored in a cloud information base. When the blood bag with the bar code A enters the labeling machine, the label strip shape code A is scanned first, and information required by printing visible characters and bar codes on the label surface of the RFID Inlay label B is transmitted according to the code link information base and is transmitted to the RFID printer to perform label printing and RFID Inlay information writing. And outputting paper and printing by the printer, and outputting labels after the Inlay writing is finished. The blood bag is conveyed to an automatic labeling machine below the labeling machine, and the label with the visible characters, the bar codes and the RFID Inlay information written in is pressed down and attached to the blood bag. And conveying the labeled blood bag to the vicinity of the outlet, and starting the code scanner and the RFID Reader above the outlet to scan the bar code data of the label B on the blood bag and read the RFID information for association confirmation. And the information is transmitted back to the cloud end for confirmation and labeling after confirmation without error, so that the record flow management is completed, and the record is ready for warehousing.

Compared with the prior art, the wireless radio frequency management equipment of the automatic printing labeling machine has the advantages that the automatic quick and full-flow traceability management of blood bags and other containers can be realized; the new label suitable for warehouse entry is utilized to replace the old label by scanning, generating the label, attaching the label, verifying the data and the like, and all or part of the data of the old label can be automatically imported into the new label, so that the accuracy of the data is improved.

The radio frequency management device and the method of the automatic printing labeling machine of the invention are further described below with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic diagram of a wireless radio frequency management device of an automatic printing labeling machine;

FIG. 2 is a process flow diagram of a wireless radio frequency management method of an automatic printing and labeling machine according to the invention;

the labels in the figures are: 2-a blood bag; 12-a server; 122-a storage unit; 16-a first component; 18-a second component; 20-a third component; FT-first tag; FD-first data; FA-first work zone; SA-second work area; TA-third working area; FIDC-first identification code; SD-second data; ST-second tag; VSD-visual second data; ESD-digitized second data.

Detailed Description

The following examples are illustrative of the invention and are not intended to limit the scope of the invention.

As shown in fig. 1, a schematic structural diagram of the management device of the present invention is shown. The wireless radio frequency management device of the automatic printing and labeling machine is applied to a biological sample container, wherein the biological sample container is a blood bag 2 in the embodiment, and can be a test tube or other containers in other embodiments. The blood bag 2 is provided with a first tag FT having a first identification code FIDC, the first tag FT stores first data FD, and the first identification code FIDC is a one-dimensional bar code or a multi-dimensional bar code pattern.

The first data FD may be one or more of a biological sample container type, a biological sample container capacity, a biological sample container number, a sampler identity, a biological sample type, a sampling time, a sampling location, a sampling date, a sampler identity.

The radio frequency management apparatus of the automatic printing and labeling machine of the present invention comprises a server 12, a delivery unit, a first assembly 16, a second assembly 18 and a third assembly 20.

The server 12 has a storage unit 122 built therein, and the storage unit 122 is used for storing the first data FD. The server 12 may be located at the local end or at the cloud end. The server 12 is provided therein with a transmission unit that can transmit the first data FD by a communication device conforming to a wired communication specification or a wireless communication specification. The medical staff member may record the first data FD related to the blood in the storage unit 122 while drawing the blood of the patient.

The conveying unit is used for conveying the blood bags 2 and comprises a single-section or multi-section conveying belt consisting of gears, motors and belt bodies. The conveying unit is provided with a first working area FA, a second working area SA and a third working area TA. In fig. 1, the first working area FA, the second working area SA, and the third working area TA are sequentially arranged from left to right. The medical staff or other staff member feeds the collected blood bag 2 from the left end of the first working area FA into the transport unit.

The first component 16 is connected to the server 12 via a wired or wireless network, the first component 16 comprises a bar code scanner, an RFID reader and a communication component, the first component 16 is configured to scan a first identification code FIDC on the blood bag 2 located in the first working area FA, and in the server 12, obtain corresponding first data FD from the storage unit 122 according to the first identification code FIDC, and transmit the first data FD to the second component 18. The first component 16 is used in a manner known in the art and will not be described in detail herein.

Second component 18 is connected to server 12 via a wired or wireless network, and second component 18 includes a bar code scanner, a processor, a memory unit, an RFID reader/writer, a communications component, and a labeling machine. The second component 18 is used in a manner known in the art and will not be described in detail herein. The second component 18 receives the first data FD information from the blood bag 2 in the first component 16, and performs data processing by the processor to convert the first data FD information into second data SD with a second identification code according to a preset data encoding rule, where the data encoding rule may be that the second data SD is identical to the first data FD, or the second data SD may be a part of the first data FD and data content that is not appeared in the first data FD, such as information of a location of a blood bank, a managed lot number, and the like. The second data SD with the second identification code is then printed visually on the label surface of the second label ST, while the second data SD is written digitally to the second label ST, which is then attached by the labeler to the blood bag 2 entering the second working area SA. The second tag ST is internally provided with a radio Frequency identification chip, the radio Frequency identification chip is used for processing and storing the second data SD, and the radio Frequency identification chip uses an Ultra-High Frequency (Ultra-High Frequency) band to store the second data SD in a digital form in the second tag ST through an RFID reader/writer. The size of the second label ST is not smaller than the size of the first label FT. The second data SD is related to the first data FD, in other words, the second data SD may be completely or partially identical to the first data FD, or the second data SD may be a part of the first data FD and additional data contents that have not been presented to the first data FD, such as information of a location of a blood bank, a lot number managed, etc. The second identification code is a one-dimensional bar code or a multi-dimensional bar code pattern.

The third component 20 is connected to the server 12 via a wired or wireless network, and the third component 20 includes a bar code scanner, an RFID reader, and a communication component. The third component 20 is used in a manner known in the art and is not described herein. The third assembly 20 is adapted to scan the second identification code of the second data VSD visible on the blood bag 2 passing through the third working area TA and to read the digitized second data ESD. When the server 12 confirms that the second data SD matches the first data FD, the management operation before the blood bag 2 is put in storage is completed. Such as logging onto the blood bag 2 to set the location, time, expiration date, etc. of the blood pool.

The invention discloses a wireless radio frequency management method of an automatic printing labeling machine, which is applied to a blood bag 2 with a first label FT, wherein the blood bag 2 is provided with first data FD, and the first label FT stores the first data FD and is provided with a first identification code FIDC. As shown in fig. 2, fig. 2 is a process flow chart of the method of the present invention, comprising the steps of:

step S21, scan the first identification code FIDC to obtain the first data FD pre-stored in the servo terminal;

a step S22 of printing the contents of the second data SD related to the first data FD on the second label ST to form visible second data VSD;

step S23, writing the content of the second data SD into the RFID chip of the second tag ST to form a digitalized second data ESD;

step S24, attaching the second label ST to the blood bag 2, so as to replace the first label FT, wherein the second label ST may cover the first label FT or be attached to another position of the blood bag 2;

step S25, scanning the visible second data VSD and reading the digitized second data ESD to compare the first data FD and the second data SD, if the first data FD and the second data SD do not match, step S26 is performed, and if the first data FD and the second data SD match, step S27 is performed;

step S26, sending a notice, returning to step S21, re-performing the steps, and re-attaching the label of the second data SD;

step S27, outputting the blood bag 2 with the second label ST, and subsequently managing according to the second label ST, for example, the blood bag 2 of the second label ST is sent to a corresponding position of a blood bank;

step S28, ending the step.

In step S25, the healthcare worker or other staff member can determine that the blood bag 2 is correct by comparing the information of the identity of the sampled person, the type of biological sample, the sampling time, the sampling place, the sampling date, the type of biological sample container, the capacity of the biological sample container, etc. in the first data FD and the second data SD.

While the invention has been described in detail in the foregoing general description and specific examples, it will be apparent to those skilled in the art that modifications and improvements can be made thereto. Accordingly, such modifications or improvements may be made without departing from the spirit of the invention and are intended to be within the scope of the invention as claimed.

Claims (8)

1. A wireless radio frequency management device for an automatic printing and labeling machine, applied to a biological sample container with a first label, the biological sample container has first data, the first label stores the first data and the first label has The first identification code is characterized by: including A server, the server is used to provide a storage unit to store the first data; A transport unit. The transport unit is used to transport biological sample containers. The transport unit is provided with a first working area, a second working area and a third working area, wherein the biological sample containers pass through the first working area and the second working area in sequence. area and third work area; The first component is connected to the server. The first component is used to scan the first identification code on the biological sample container in the first work area, and obtain the corresponding information from the storage unit according to the first identification code. the first data; The second component is connected to the server. The second component is used to receive the first data scanned in the first component and print the second data with the second identification code on the label surface of the second label and The second data is written into a second label, and the second label is affixed to the biological sample container located in the second work area, wherein the second data provided by the second label includes both visual and digital form; and The third component is connected to the server. The third component is used to scan the second identification code of the visible second data and read the electronic second data, and confirm the second data on the server. When the first data is met, the pre-warehousing management of biological sample containers is completed; The first identification code and the second identification code are one-dimensional barcodes or two-dimensional barcodes; The size of the second label is not smaller than the size of the first label. 2. The wireless radio frequency management device of the automatic printing and labeling machine according to claim 1, characterized in that: the first data and the second data include biological sample container type, biological sample container capacity, biological sample container number, At least one of the identity of the person being sampled, the type of biological sample, the time of sampling, the location of sampling, the date of sampling, or the identity of the sampler. 3. The wireless radio frequency management device of the automatic printing and labeling machine according to claim 1, characterized in that: the second label includes a radio frequency identification chip, and the radio frequency identification chip is used to process and store the second data. . 4. The radio frequency management device of the automatic printing and labeling machine according to claim 3, characterized in that: the radio frequency identification chip uses an ultra-high frequency band. 5. The wireless radio frequency management device of the automatic printing and labeling machine according to claim 1, characterized in that the conveying unit is a single-section or multiple-section conveyor belt. 6. A radio frequency management method for an automatic printing and labeling machine, applied to a biological sample container with a first label, the biological sample container has first data, the first label stores the first data and the first label has The first identification code is characterized by: including the following steps: S1, scan the first identification code and obtain the first data pre-stored on the server; S2, print the content of the second data related to the first data on the second label to form visible second data; S3: Write the content of the second data in the radio frequency identification chip of the second tag to form digital second data; S4, attach the second label to the biological sample container to replace the first label; S5, scan the visible second data and read the digital second data, compare the first data and the second data, if the first data and the second data do not match, proceed to step S6, if the first data and the second data If consistent, proceed to step S7; S6, issue a notification and return to step S1; S7, output the biological sample container with the second label; and S8, end step. 7. The wireless radio frequency management method of the automatic printing and labeling machine according to claim 6, characterized in that after step S7, the biological sample container with the second label is sent to the corresponding location in the blood bank. 8. The wireless radio frequency management method of the automatic printing and labeling machine according to claim 6, characterized in that: in step S4, the second label covers the first label so that the second label replaces the first label.