JP2006139582A - Recording device and communication control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a recording medium for detecting the detail of error contents when any "data write error" occurs, and for reporting the result to a user. <P>SOLUTION: When "RF-ID data write error" occurs, the unique ID is read, and the error contents are detected according to the read number of the unique ID. For example, when the number is zero, non-detection is reported, when the number is one, RFID failure is reported, and when the number is two or more, the multi-feeding of a medium is reported. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a recording apparatus and a communication control method for performing recording on an RF-ID element built-in recording medium and writing on an RF-ID element in parallel.

  2. Description of the Related Art Conventionally, an RF-ID (Radio Frequency IDentification) element including an integrated circuit chip capable of writing / reading information without contact and a communication antenna has been developed. Usually, the RF-ID element is built in a medium such as label paper, tag paper, cut paper, and plastic card.

  When writing / reading information to / from an RF-ID element built in a medium, an RF-ID communication control device incorporating an “RF-ID communication driver” for communicating with the RF-ID element is used. By using and driving the RF-ID communication driver and communicating with the RF-ID element built in the medium, information is written to / read from the RF-ID element.

  In recent years, a recording device has been developed that incorporates an RF-ID communication driver in the recording device and records information on the surface of a recording medium containing the RF-ID element in the recording device at the same time as writing information to the RF-ID device. Has been.

In a card recording device with a built-in non-contact IC reader / writer, information can be written to the non-contact IC built in the recording medium to be fed, and further recording can be performed on the surface of the recording medium. However, when a “data writing error” occurs in a non-contact IC, it is treated as the same error regardless of the state of the recording medium or the non-contact IC.
(For example, Patent Document 1)
Furthermore, in a label recording apparatus similar to the above, it is possible to write information on a non-contact IC built in the label and further record on the label surface. When a “data writing error” occurs, it is treated as the same error regardless of the state of the label or non-contact IC.
(For example, Patent Document 2)

JP 2003-150907 A JP2003-303320A

However, the above prior art has the following problems.

  That is, if an error occurs during writing to a non-contact IC, it is treated as a “data write error” regardless of the state of the medium or the non-contact IC, and the user is notified, so that the non-contact IC is not defective. Even so, the user determines that the non-contact IC is defective and discards the medium in which the error has occurred. However, a write error does not occur only with a non-contact IC failure. For example, when media are overlapped and fed (multiple feed), a communication error occurs even when a plurality of non-contact ICs exist in the communication range of the communication antenna of the reader / writer.

  FIG. 8A shows a state in which the recording medium (0802) is normally transported to the communication range (communication available region) of the RF-ID communication antenna (0102), and the communication range (0801) of the RF-ID antenna (0102). ) Has only one RF-ID element (0803). In this case, information can be written in a normal sequence.

  FIG. 8B shows a state in which the recording medium (0804/0806) is double-fed, and there are two RF-ID elements (0805/0807) in the communication range (0801) of the RF-ID antenna (0102). is doing. In this case, a normal sequence cannot be maintained, resulting in an RF-ID data write error.

  The present invention has been made in view of the above-described points, and an object of the present invention is to provide a recording apparatus capable of detecting details of an error content and informing a user when a “data write error” occurs. And

In order to achieve the above object, the recording apparatus of the present invention comprises:
A recording device having a communication control means for performing contactless communication with a communication element including a memory built in a medium, the communication element number detecting means for detecting the number of the communication elements existing in a communication range of a communication antenna; An information writing means for writing information into the memory, and a writing check means for checking whether the writing has been normally performed,
It is further characterized by further comprising an error notifying means for notifying an error related to the number of communication elements detected by the communication element number detecting means when writing is not normally performed.

The communication control method according to the present invention includes:
A communication control method for performing contactless communication with a communication element including a memory built in a medium, wherein the number of communication elements is detected in a communication range of a communication antenna; An information writing process for writing information, and a writing check process for checking whether writing has been performed normally,
The method further comprises an error notification step of notifying an error related to the number of communication elements detected by the communication element number detection step when writing is not normally performed.

Furthermore, the recording apparatus of the present invention includes:
A recording device having a communication control means for performing non-contact communication with a communication element including a memory built in a medium, the communication element number detecting means for detecting the number of the communication elements existing in a communication range of a communication antenna Prepared,
When there are a plurality of results detected by the communication element number detection means,
It is characterized in that an alarm indicating that the medium is double fed is sent.

  As described above, according to the present invention, when an “RF-ID data write error” occurs, the details of the error content can be detected and the correct error content can be notified to the user.

Hereinafter, embodiments of the present invention will be described in detail based on examples.
(First embodiment)
FIG. 2 is a schematic diagram of a recording medium with a built-in RF-ID element used in the present invention. The recording medium (0106) is a sheet-like cut card, and an RF-ID element (0107) is built in the recording medium. The RF-ID element (0207) includes an antenna unit and an RF-IDIC chip, and reads, writes, and stores information through communication with the RF-ID communication antenna on the recording apparatus main body side. Each RF-ID element (0207) has an individual ID such as a unique ID, and the unique ID can be read via the RF-ID communication antenna.

  FIG. 1 is a sectional view of a recording apparatus (0100) of the present invention.

  The recording device (0100) is equipped with a fixed communication antenna (0106) for communicating with an RF-ID element (0107) built in the recording medium (0108) to read / write information.

  After feeding the recording medium loaded on the feeding tray (0103) of the feeding section (0101), the recording medium is conveyed by the conveying belt (0110), and the leading edge of the recording medium is detected by the TOF sensor (0109). (0110) is stopped. In this state, after performing control to write information to the RF-ID element (0107) built in the recording medium (0108) via the communication antenna (0106), the conveyor belt is driven again, black, The recording data for each color is color-recorded on the surface of the recording medium (0108) by the cyan, magenta, and yellow recording heads (0104K to 0104Y) and stacked on the paper discharge tray (0102).

  FIG. 3 shows a configuration diagram in which a host computer is connected to the recording apparatus of the present invention.

  A recording device (0100) and a host computer (0301) are installed and connected by a printer cable (0302). The host computer (0301) transmits a control command to the recording device (0100) via the printer cable (0302).

  FIG. 10 shows the structure of a control command transmitted from the host computer used in this embodiment. As control commands, a paper setting command (1001) for setting the size of a recording medium to be recorded, a format command (1002) having a setting serving as a reference for recording data, a data command for setting detailed information of characters, images, and RFID Attribute portion (1003, 1004, 1005) and data portion, and (1006) a recording start command (1007) that indicates the end of the recording data and starts recording, and these commands are recorded as in the recording command transfer example (1008). Output to.

  FIG. 9 shows the operation unit of the recording apparatus used in this embodiment. It comprises an LCD (0412) for displaying the status of the recording device, an error (0414) for notifying the error status of the recording device, and an error clear key (0413) for canceling the error status when an error occurs.

  FIG. 4 shows an electric circuit block diagram of the recording apparatus (0100) in this embodiment. The CPU (0401) in the recording device (0100) receives control commands such as recording data and RF-ID writing information from the host computer (0301) via the host interface (0407), and the image data is image data. -The image data is stored in the image RAM (0404) by directly developing the bitmap, and the character data is read out from the font data specified from the CG-ROM (403), and the processing specified in the command is performed to perform the image RAM (0404). ) Is stored by developing a bitmap, and RF-ID write information is stored in the work RAM (0405). Upon reception of the recording start command (1007), the CPU (0401) monitors input signals from the TOF sensor (0109), feeding sensor (112), and paper surface sensor (0115) via the input / output port (0410). However, by controlling the various motor drivers (0411) via the input / output port (0410), the conveyance motor (0111), the feeding motor (0113), and the tray motor (0116) are driven to start the recording operation. -Gave it. After feeding the recording medium to the TOF sensor (0109), the CPU (0401) reads the RF-ID writing information stored in the work RAM (0405), and the RF-ID communication antenna via the RF-ID reader / writer (0409). The RF-ID writing information is transmitted to (0106), and control is performed to write the information to the RF-ID element (0107). Next, the CPU (0401) starts reading the image RAM (0404), sequentially transfers the recording data to each recording head (0104) via the head driving circuit (0408), and performs color recording on the recording medium. To do. These series of operations are executed by the CPU (0401) based on the program stored in the program ROM (0402). The CPU (0401) also uses the work RAM (0405) as a working memory required for execution. In addition, the LCD (0413) is driven by monitoring the input signal from the key (0414) mounted on the operation unit, controlling ON / OFF of the LED (0415), and controlling the LCD driver (0412).

  FIG. 5 is a flowchart showing recording processing of the recording medium in the present embodiment. The character (1003) and image command (1004) received from the host computer in the recording data expansion process (S501) are expanded in the image RAM (0404), and the write information of the RF-ID command (1005) is stored in the work RAM (0405). save. When the recording start command (1007) is received, the driving of the carry motor is started (S502), and the paper feed process (S503) is also started in parallel.

  When the leading edge of the sheet fed and transported by the TOF sensor is detected (S504: “YES”), it is checked whether the command received from the host computer includes an RF-ID command (S505).

  If the RF-ID command is included (S505: “YES”), the transport motor is stopped (S510), the write information is read from the work RAM (0405), and written to the RF-ID element (0107) (S511). )I do. Next, it is checked whether or not the writing to the RF-ID element has been completed normally (S512). If the error has ended (S512 is “YES”), an error process (S514) is executed, and the recording process ends. . When the writing to the RF-ID element is normally completed (S512 is “NO”), the driving of the transport motor is started (S513), recording is performed on the surface of the recording medium in the printing process (S506), and the paper discharge process is performed. In step S507, the recording medium is discharged to the paper discharge tray, the transport motor is stopped (S508), whether the next recording data is received (S509), and the next data is not received (S513). Is “NO”), the recording process ends. If the RF-ID command is not included (S505: “NO”), the RF-ID writing process is not performed, and the printing process (S506) is continuously performed.

  FIG. 6 is a flowchart showing the recording medium feeding process in this embodiment. When the paper feed tray starts to rise (S601) and the paper surface sensor (0115) detects the paper surface of the recording medium (S602 “YES”), the paper feed tray (0103) is stopped. Next, the driving of the feeding motor (0113) is started, and when the leading edge of the recording medium is detected by the feeding sensor (0112) (“YES” in S605), the driving of the feeding motor (0113) is stopped ( S606) Feeding of one sheet is completed.

  FIG. 7 is a flowchart showing RF-ID write error processing in this embodiment. The unique ID of the RF-ID element in the communication range of the communication antenna is read via the communication antenna (S701).

  If the unique ID could not be read (S702: “YES”), the RF-ID element of the recording medium could not be detected, so an “RF-ID non-detection error” was displayed on the LCD of the operation unit ( S703) If only one unique ID can be read (“YES” in S704), there is a possibility that the memory of the RF-ID element built in the recording medium may be defective. When “RF-ID failure error” is displayed (S705) and a plurality of unique IDs can be read (“YES” in S704), since there are a plurality of recording media in the communication range of the communication antenna, “LCD” on the operation unit displays “ “RF-ID double feed error” is displayed (S706). Then, the error LED is turned on (S707), and then the error clear key is pressed (S708 is “YES”), the error LED is turned off (S709), and “ready” indicating that the error is released is displayed on the LCD. .

As described above, in the first embodiment, as shown in the flowchart of FIG. 7, after the RF-ID communication error occurs, the unique ID is read and the number of RF-ID elements in the communication range of the communication antenna is detected. Then, by selecting the content of the error message to be displayed on the LCD according to the detected number, it is possible to determine whether it is an “error caused by defective RF-ID element” or “an error caused by double feeding of the recording medium”. The user can easily identify.
(Second embodiment)
This embodiment can be implemented by displaying the number of unique IDs read by the communication antenna when an RF-ID write error occurs in the first embodiment.

  FIG. 11 is a flowchart showing RF-ID write error processing in this embodiment.

  The unique ID of the RF-ID element within the communication range of the communication antenna is read via the communication antenna (S1101), and “RF-ID failure error: ID = XX” (“XX” is read) on the LCD of the operation unit. The number of unique IDs) is displayed (1102). Then, the error LED is turned on (1103), and then the error clear key is pressed (S1104 is “YES”), the error LED is turned off (S1105), and “ready” indicating that the error is released is displayed on the LCD. (1106).

Thus, in the second embodiment, as shown in the flowchart of FIG. 11, after an RF-ID communication error occurs, the unique ID is read and the number of RF-ID elements in the communication range of the communication antenna is determined. By detecting and displaying an error message including the detected number, the user can easily identify whether the error is caused by a defective RF-ID element or an error caused by double feeding of the recording medium. it can.
(Third embodiment)
This embodiment can be implemented by blinking the LED as many times as the number of unique IDs read by the communication antenna when an RF-ID write error occurs in the first embodiment.

  FIG. 12 is a flowchart showing RF-ID write error processing in this embodiment.

  The unique ID of the RF-ID element within the communication range of the communication antenna is read via the communication antenna (S1201), and an “RF-ID failure error” is displayed on the LCD of the operation unit (S1202). Then, the error LED is blinked as many times as the number of unique IDs read at intervals of 500 milliseconds (S1203), waits for 2 seconds (S1204), and then the error clear key is pressed (S1205 is “YES”), the LCD displays “Ready” is displayed to indicate that the error has been cleared. When the error clear key is not pressed (S1205 is “NO”), the LED is blinked again.

Thus, in the third embodiment, as shown in the flowchart of FIG. 12, after an RF-ID communication error occurs, the unique ID is read, and the number of RF-ID elements in the communication range of the communication antenna is determined. By detecting and blinking the LED for the detected number of times, it is possible to easily identify whether the error is an error caused by a defective RF-ID element or an error caused by double feeding of the recording medium. .
(Other examples)
The present invention relates to a recording method such as a label recording apparatus capable of recording a long sheet of paper with a plurality of labels attached thereto, a recording apparatus of a type in which a recording head is scanned perpendicularly to the paper conveyance direction, It can be applied to other recording methods such as an ink jet recording apparatus, a thermal recording apparatus, a thermal transfer recording apparatus, and electrophotography.
Further, in the first embodiment, the conveyance of the recording medium is temporarily stopped in order to reliably perform communication when data is written to the RF-ID element, but the RF- Data may be written by communicating with the ID element.

  The present invention can be used in a recording apparatus in which an RF-ID communication driver is built in the recording apparatus and information is recorded on the built-in RF-ID element at the same time recording is performed on the surface of the recording medium.

It is sectional drawing of the recording device used in the 1st-3rd Example. It is a schematic diagram of the recording medium with a built-in RF-ID element used in the first to third embodiments. It is a block diagram which connected the host computer to the recording device in the 1st-3rd Example. It is an electrical block diagram of the recording apparatus used in the first to third embodiments. It is a flowchart of the recording process in the 1st-3rd Example. It is a flowchart of the paper feed process in the first to third embodiments. It is a flowchart of the RF-ID write error process in the first embodiment. It is a figure which shows the state in which the recording medium was conveyed by the communication range of the communication antenna. It is an operation part of the recording apparatus used in the first to third embodiments. It is a figure which shows the structure figure and example of transmission of the control command transmitted from the host computer used in the 1st-3rd Example. It is a flowchart of the RF-ID write error process in the second embodiment. It is a flowchart of the RF-ID write error process in the third embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 0100 Recording apparatus 0101 Feed part 0102 Paper discharge tray 0103 Paper feed tray 0104 Recording head 0105 Printing part 0106 RF-ID communication antenna 0107 RF-ID element 0108 Recording medium 0109 TOF sensor 0110 Conveyance belt 0111 Conveyance motor 0112 Feed sensor 0113 Feed Feed motor 0114 Feed roller 0115 Paper surface sensor 0116 Tray motor 0116 Tray belt 0301 Host computer 0302 Printer cable

0401 CPU
0402 Program ROM
0403 CG-ROM
0404 Image RAM
0405 Work RAM
0407 Host interface 0408 Head drive circuit 0409 RF-ID communication antenna interface 0410 I / O port 0411 Various motor drivers 0412 LCD driver 0413 LCD
0414 Error clear key 0415 Error LED

0801 RF-ID antenna communication range 0802 Recording medium 0803 RF-ID element 0804 Recording medium 0805 RF-ID element 0806 Recording medium 0807 RF-ID element

1001 Paper setting command 1002 Format command 1003 Character data command attribute part 1004 Image data command attribute part 1005 RF-ID data command attribute part 1006 Data command data part 1007 Recording start command

Claims (14)

A recording device having a communication control means for performing contactless communication with a communication element including a memory built in a medium, the communication element number detecting means for detecting the number of the communication elements existing in a communication range of a communication antenna; An information writing means for writing information into the memory, and a writing check means for checking whether the writing has been normally performed,
A recording apparatus, further comprising: an error notification unit that notifies an error related to the number of communication elements detected by the communication element number detection unit when writing is not performed normally. The recording apparatus according to claim 1, wherein the communication element number detection unit reads identification information unique to a communication element existing in a communication range of the communication antenna. The recording apparatus according to claim 2, wherein an error content related to the number of identification information read by the error notification unit is notified. 4. The recording apparatus according to claim 2, wherein when the number of identification information read by the error notification means is zero, notification is made that a communication element is not built in the medium. The recording apparatus according to claim 2, wherein when the number of identification information read by the error notification unit is one, a notification that the communication element is defective is provided. 6. A recording apparatus according to claim 2, wherein when there are two or more pieces of identification information read by said error notification means, notification is made that a plurality of sheets are being double-fed. The recording apparatus according to claim 1, wherein the notification unit displays a message on a display unit. The recording apparatus according to claim 1, wherein the notification unit resonates a buzzer. The communication control device according to claim 1, wherein the notification unit blinks an LED. The recording apparatus according to claim 1, wherein the notification means uses a voice message.
The recording apparatus according to claim 1, wherein the medium includes cut paper, a plastic card, and a long paper temporarily attached with a plurality of labels. A communication control method for performing contactless communication with a communication element including a memory built in a medium,
A communication element number detecting step for detecting the number of communication elements existing in a communication range of a communication antenna; an information writing step for writing information into the memory; and a write check step for checking whether the writing has been normally performed. ,
A communication control method, further comprising: an error notification step of notifying an error related to the number of communication elements detected by the communication element number detection step when writing is not normally performed. A recording device having a communication control means for performing non-contact communication with a communication element including a memory built in a medium, the communication element number detecting means for detecting the number of the communication elements existing in a communication range of a communication antenna Prepared,
When there are a plurality of results detected by the communication element number detection means,
A recording apparatus which sends an alarm indicating that a medium is double-fed. The recording device or the communication control method according to claim 1, wherein the communication element number detection unit reads an ID unique to the communication element.

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