JP2010198416A - Recording device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a recording device which reliably and easily determines whether MICR (magnetic ink character recognition) information is read successfully or not. <P>SOLUTION: The recording device includes an MICR magnetic head 65 disposed between a second driving roller 23A and a third driving roller 124A to read the MICR information recorded in a sheet-shaped recording medium S. A sheet conveying mechanism 100, which can discharge the recording medium S in at least two different directions, discharges the sheet-shaped recording medium S from different discharge ports depending on whether MICR information is successfully read by the MICR magnetic head 65. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a recording apparatus including a magnetic head that reads MICR information recorded on a sheet-type recording medium.

  In general, a booklet-type recording medium (for example, a passbook) having a magnetic recording unit, and a sheet-type recording medium (for example, a check (personal check, etc.)) on which magnetic ink character information (hereinafter referred to as MICR information) is recorded. A recording apparatus is known that records character information on a booklet-type recording medium and a sheet-type recording medium (see, for example, Patent Document 1). When reading the MICR information, when the sheet-type recording medium is supplied from the manual feed slot of the recording apparatus, the recording medium is magnetically Then, the magnetic head reads the MICR information and the recording medium after the reading is discharged from the discharge port. Air head result of whether the reading of the MICR information was successful by is output to the display of the host computer connected to the recording apparatus, the results the user has been confirmed by visual observation.

Japanese Patent Laid-Open No. 2002-28891

  For this reason, in the conventional configuration, there is a problem that the user needs to check one by one as to whether or not the MICR information has been successfully read, which increases the burden on the user. Further, since the recording medium after reading is discharged from a single discharge port regardless of whether the reading of MICR information is successful or unsuccessful, the user can display the display result when reading a plurality of recording media. As a result, it is assumed that the recording medium that has successfully read the MICR information cannot be reliably distinguished from the recording medium that has failed.

  Accordingly, an object of the present invention is to provide a recording apparatus that solves the above-described problems of the conventional technology and can reliably and easily determine whether or not MICR information has been successfully read. It is in.

  In order to achieve the above object, the present invention is configured to be capable of transporting a booklet-type recording medium having a magnetic recording section and a sheet-type recording medium on which MICR information is recorded, and the booklet-type recording medium, In the recording apparatus for recording on the sheet-type recording medium, the booklet-type recording medium and a transport mechanism having a plurality of rows of transport rollers arranged in the transport direction of the sheet-type recording medium, and the magnetism of the booklet-type recording medium A first magnetic head that reads a recording unit; and a second magnetic head that is disposed between the plurality of rows of conveyance rollers and that reads MICR information recorded on the sheet-type recording medium. The mechanism can eject the recording medium in at least two different directions, and if the MICR information is successfully read by the second magnetic head, the mechanism reads the MICR information. The discharge direction different from the case of failure to Ri, characterized in that for discharging the sheet type of the recording medium.

  According to this configuration, when the reading of the MICR information by the second magnetic head is successful, the sheet-type recording medium is discharged in a different discharge direction from that when the reading of the MICR information has failed. All the recording media ejected from the recording medium were successfully read by the second magnetic head, and it was confirmed whether or not the MICR information was successfully read simply by collecting the materials ejected from the ejection port. And can be easily discriminated.

In this configuration, when the transport mechanism has succeeded in reading the MICR information by the second magnetic head, the transport mechanism discharges the sheet-type recording medium from the discharge port on the side closer to the second magnetic head. It is good also as composition to do.
According to this configuration, when the MICR information is successfully read by the second magnetic head, the sheet-type recording medium is discharged from the discharge port on the side closer to the second magnetic head. The distance and the conveyance time can be shortened, and the processing capacity per unit time can be improved.

Further, in this configuration, when the MICR information has been successfully read by the second magnetic head, the ejection direction is different from that in the case where the MICR information has failed to be read and the booklet-type recording medium is ejected. The sheet type recording medium may be discharged.
According to this configuration, when the MICR information is successfully read by the second magnetic head, the sheet-type recording is performed in a different discharge direction from the case where the MICR information reading is unsuccessful and when the booklet-type recording medium is discharged. In order to discharge the medium, it is possible to reliably and easily determine whether or not the MICR information has been successfully read by simply collecting the medium discharged from the discharge port in the discharge direction.

Further, in this configuration, a magnetized portion that magnetizes the magnetic ink characters that constitute the MICR information may be provided at a position outside the area where the magnetic recording portion of the booklet type recording medium is conveyed. good.
According to this configuration, since the magnetized portion is provided at a position outside the area where the magnetic recording portion of the booklet type recording medium is conveyed, the magnetic recording portion of the booklet type recording medium passes through the magnetized portion. Is prevented. According to this, contact or proximity between the magnetized portion and the magnetic recording portion is prevented, and the magnetized portion does not destroy the magnetic information of the magnetic recording portion, and the influence on the magnetic recording portion of the booklet type recording medium. Therefore, it is possible to prevent occurrence of a reading error in the magnetic recording portion of the booklet type recording medium.

  According to the present invention, when the reading of the MICR information by the second magnetic head is successful, the sheet-type recording medium is discharged in a different discharge direction from that when the reading of the MICR information has failed. All the recording media ejected from the recording medium were successfully read by the second magnetic head, and it was confirmed whether or not the MICR information was successfully read simply by collecting the materials ejected from the ejection port. And can be easily discriminated.

1 is an external perspective view of a dot impact printer in the present embodiment. FIG. 2 is a perspective view showing a printer body. FIG. 3 is a side sectional view of the printer body. It is a perspective view which shows the arrangement configuration of a MICR magnetic head. It is a block diagram which shows the functional structure of a dot impact printer. It is a flowchart which shows operation | movement of a dot impact printer.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a front perspective view showing an appearance of a dot impact printer as a recording apparatus according to the present embodiment. FIG. 2 is an external perspective view showing the printer main body 11. FIG. 3 is a side sectional view showing the dot impact printer 10 of FIG.
A dot impact printer 10 as a recording apparatus shown in FIG. 1 is connected to a host computer described later, receives print data transmitted from the host computer, and prints (records) on a recording medium based on the received print data. Do. Specifically, the dot impact printer 10 is a sheet-type printer that uses a plurality of recording wires provided in the recording head 18 (see FIGS. 2 and 3) via an ink ribbon (not shown) that is fed from a ribbon cartridge (not shown). The recording medium S (hereinafter simply referred to as the recording medium S) or a booklet type recording medium T (hereinafter simply referred to as the recording medium T) is pressed to form dots on the recording surface of the recording medium S or the recording medium T. As a result, an image including characters is printed (recorded). The print data described above may include data such as characters, symbols and images to be printed, a control command for instructing printing execution, a control command for specifying a printing range and a printing position, and other control information.

Recording media that can be used with the dot impact printer 10 include a cut sheet cut to a predetermined length and a continuous sheet in which a plurality of sheets are connected. Examples of cut sheets include plain paper such as single-cut paper and single-sheet copy paper, as well as passbooks, postcards, and envelopes. Continuous paper includes continuous copy paper.
In the present embodiment, a check (personal check) issued by a financial institution or the like is used as the recording medium S, and a passbook issued by the financial institution or the like is used as the recording medium T.
The check is a sheet of paper in which MICR (Magnetic Ink Character Recognition) information such as the user's account number and the serial number of the check is printed on a part of the area MA on the surface by magnetic ink.
The passbook is in the form of a booklet in which a plurality of recording sheets are bound, and the inner surface of the booklet is the recording surface. A magnetic stripe (magnetic recording portion) MS is provided on the rear end side of the surface corresponding to the back cover of the passbook.
In the following description, of the four sides of the recording medium S or the recording medium T, a side inserted toward the dot impact printer 10 is a leading end, and a side facing the leading end is a rear end.

As shown in FIG. 1, the dot impact printer 10 includes an upper cover 12, an upper case 13, and a lower case 14 as exterior bodies, and a recording medium S is inserted in front of the upper case 13 and the lower case 14. Or the manual feed port 15 which discharges is opening. On the other hand, the rear surface of the upper cover 12 and the upper case 13 is provided with a discharge portion 7 that protrudes rearward, and on the upper surface of the discharge portion 7, the recording medium S inserted from the manual feed port 15 is provided. A discharge port 8 through which the part is discharged is open. As shown in FIG. 3, the discharge port 8 is connected to a conveyance path P through which the recording medium S is conveyed through the dot impact printer 10, and has a radius that does not cause paper jam in the discharge unit 7. A communication path 9 that is formed to communicate the transport path P and the discharge port 8 is formed. A plurality of ribs 8 </ b> A arranged at predetermined intervals are provided on the wall surface of the communication passage 9 on the discharge port 8 side.
As described above, the dot impact printer 10 of this configuration includes the manual feed port 15 and the discharge port 8, and the recording medium S inserted from the manual feed port 15 is placed in at least two different directions, that is, the manual feed port 15 or It can be selectively discharged from any of the discharge ports 8. Further, the side where the manual feed opening 15 is opened, that is, the left side in FIG. 1 is the front (front) side, and the right side in FIG. 1 is the rear (rear) side.

  As shown in FIG. 2, the dot impact printer 10 includes a printer main body 11 covered with an upper cover 12, an upper case 13, and a lower case 14. The printer main body 11 includes a lower main body portion 11A and an upper main body portion 11B supported by a shaft 11C at the rear end portion of the lower main body portion 11A. If the upper main body 11B is rotated about the shaft 11C when the upper cover 12 is opened, the inside of the printer main body 11 is exposed.

3 and 4, the printer main body 11 includes a main body frame including a base frame 16, a right side frame 17A, and a left side frame 17B (FIG. 4), a recording mechanism including a recording head 18 and a carriage 19. The magnetic information of the magnetic stripe provided on the booklet-type recording medium S such as a passbook, the sheet conveying mechanism (conveying mechanism) 100 for conveying the recording medium S, the alignment plate 28 for aligning the recording medium S, A magnetic data reading unit 29 having a magnetic head (first magnetic head) 34 for reading or writing and a sheet pressing unit 30 for pressing the lifting of the recording medium S from above when reading / writing magnetic information are provided.
The sheet conveying mechanism 100 includes a platen 21, a first driving roller 22A, a first driven roller 22B, a second driving roller 23A, a second driven roller 23B, a third driving roller 124A, a third driven roller 124B, and a fourth driving roller 125A. The fourth driven roller 125 </ b> B, the front sheet guide 24, the rear sheet guide 25, the sheet conveyance motor 26, and the drive wheel train 27 are configured.

  At substantially both ends of the base frame 16, a right side frame 17A and a left side frame 17B are erected and fixed. A carriage guide shaft 31 is bridged between both side frames of the upper main body 11B. A flat seat-shaped front seat guide 24 and rear seat guide 25 are fixedly provided between the side frames 17A and 17B. A planar platen 21 is disposed between the front seat guide 24 and the rear seat guide 25. A recording head 18 is arranged above the platen 21 so as to face the platen 21.

The carriage 19 is slidably inserted into the carriage guide shaft 31 and is driven via a timing belt (not shown) by forward or reverse rotation of a carriage drive motor (see FIG. 5) that drives the carriage 19. It is guided by the guide shaft 31 and reciprocated. The moving direction of the carriage 19 is the main scanning direction that coincides with the direction indicated by the symbol X in FIG. 2, that is, the axial direction of the carriage guide shaft 31 and the longitudinal direction of the platen 21. The range of movement (scanning) of the carriage 19 is between the pair of side frames 17A and 17B. Note that the direction orthogonal to the main scanning direction X of the carriage 19, that is, the direction indicated by the symbol Y in FIG.
While the recording head 18 mounted on the carriage 19 travels in the main scanning direction together with the carriage 19 based on the print data, the recording wire is fed from a wire protrusion (not shown) facing the platen 21 at the front end surface thereof. Make it protrude and hit the ink ribbon. Thereby, the ink of the ink ribbon is attached to the recording medium S or the recording medium T conveyed between the platen 21 and the recording head 18, and an image including characters on the recording surface of the recording medium S or the recording medium T is formed. Printed. The ink ribbon is folded and stored in the ribbon cartridge 39 mounted on the main body frame or the carriage 19 and is fed out as the carriage 19 is scanned.

  The platen 21 extends in the traveling direction of the carriage 19 and is formed in a planar shape. Both ends of the platen 21 are urged toward the recording head 18 by urging springs 41 and are elastically supported. The urging spring 41 is a compression coil spring, and the urging force of the urging spring 41 supports the projecting output of the recording wire during the recording operation of the recording head 18. Further, the platen 21 is provided with the recording medium S or the recording medium T having a different thickness in the printer body 11 when the recording medium S or the recording medium T changes in thickness while the recording medium S or the recording medium T is being conveyed. When it is carried in, it moves against the urging force of the urging spring 41 and is moved away from the recording head 18 by being pressed by the tip of the recording head 18. This ensures a constant gap between the tip of the recording head 18 and the recording surface of the recording medium S or recording medium T regardless of the thickness of the recording medium.

As shown in FIG. 3, the sheet conveying mechanism 100 includes a first driving roller 22 </ b> A and a first driven roller 22 </ b> B arranged on the front side of the printer main body 11 with respect to the platen 21 and the recording head 18. Further, the second driving roller 23A, the second driven roller 23B, the third driving roller 124A, the third driven roller 124B, the fourth driving roller 125A, and the fourth driven roller 125B are connected to the platen 21 and the recording head 18 with respect to the printer body. 11 are sequentially arranged on the rear side. The first to fourth driving rollers 22A to 125A and the first to fourth driven rollers 22B to 125B are arranged in the up-down direction to make a pair.
The first driving roller 22A, the second driving roller 23A, the third driving roller 124A, and the fourth driving roller 125A are driving rollers that are rotationally driven by the sheet conveying motor 26 and the driving wheel train section 27, and the first driven roller 22B. The second driven roller 23B, the third driven roller 124B, and the fourth driven roller 125B have predetermined pressing forces on the first driving roller 22A, the second driving roller 23A, the third driving roller 124A, and the fourth driving roller 125A side, respectively. The driven rollers are spring-biased by springs 42A, 42B, 42C, and 42D, respectively. As a result, the first to fourth drive rollers 22A to 124A and the first to fourth driven rollers 22B to 124B are rotationally driven in opposite directions, and the recording medium S or the recording medium T sandwiched between these rollers is Be transported.

As shown in FIG. 2, the drive wheel train 27 is disposed outside the right side frame 17A. The drive wheel train 27 includes a motor pinion 51 that is fixed to the drive shaft of the sheet conveying motor 26 that can be rotated forward or reverse. The driving force from the motor pinion 51 is transmitted to the second driving gear 53B attached to the second roller shaft 33 of the second driving roller 23A via the reduction gear 52, and further from the second driving gear 53B to the middle. It is transmitted to the first drive gear 53A attached to the first roller shaft 32 of the first drive roller 22A via the gear 54. Further, between the second roller shaft 33 of the second drive roller 23A and the third roller shaft 134 of the third drive roller 124A, the third roller shaft 134 and the fourth roller shaft 135 of the fourth drive roller 125A. As shown in FIG. 4, the first transmission belt 140 and the second transmission belt 141 are respectively wound around, and the rotational force of the second drive roller 23 </ b> A passes through the transmission belts 140 and 141. It is transmitted to the third drive roller 124A and the fourth drive roller 125A.
Accordingly, the first driving roller 22A, the second driving roller 23A, the third driving roller 124A, and the fourth driving roller 125A rotate in the same direction, and the recording medium S or the recording medium T can be conveyed into the printer main body 11. To do. That is, the first driving roller 22A, the second driving roller 23A, the third driving roller 124A, and the fourth driving roller 125A are arranged in the sub-scanning direction when the sheet conveying motor 26 is rotating forward as shown in FIG. Accordingly, as indicated by a symbol A in the figure, the recording medium S is transported in the direction in which the recording medium S is discharged from the manual feed port 15 into the printer main body 11 or from the discharge port 8 of the discharge unit 7. When the sheet conveying motor 26 is reversely rotated, the recording medium S is conveyed in the direction in which the recording medium S is discharged from the manual feed slot 15 as indicated by reference numeral B in the drawing.

  The alignment plate 28 corrects the inclination (skew) of the recording medium S when an image is recorded by the recording head 18, and the front side of the printer body 11 with respect to the platen 21 as shown in FIG. Are arranged along the platen 21. The alignment plate 28 protrudes into the conveyance path P by the operation of the alignment plate drive motor 64 (see FIG. 5) when the recording medium S is conveyed to the front of the platen 21. The recording medium S is further conveyed while being in contact with the alignment plate 28, whereby the inclination of the recording medium S is corrected and aligned.

Further, as shown in FIG. 4, between the second drive roller 23A and the third drive roller 124A, an MICR magnetic head (first output) for reading MICR information printed on a sheet type recording medium S such as a check. 2 magnetic head) 65 is provided. The MICR magnetic head 65 is fixed on the base frame 16 so as to be exposed in the conveyance path P, and faces the area MA on which the MICR information of the recording medium S is printed when the sheet type recording medium S is conveyed. It is provided in the position to do. As a result, the area MA provided in the recording medium S passes over the MICR magnetic head 65 simply by conveying the sheet type recording medium S using the sheet conveying mechanism 100, so that the area MA is printed. The MICR information can be easily read by the MICR magnetic head 65.
Further, a permanent magnet (magnetization) for magnetizing magnetic ink on which MICR information is printed on the base frame 16 is provided on the front side of the MICR magnetic head 65, that is, between the MICR magnetic head 65 and the second drive roller 23A. (Magnetic part) 66 is provided. The permanent magnet 66 conveys the magnetic stripe MS of the booklet type recording medium T so that information written on the magnetic stripe MS of the booklet type recording medium T is not affected by the magnetic force of the permanent magnet 66. It is located at a position outside the area. Specifically, even when the booklet-type recording medium T is transported to the farthest rear in the printer main body 11, the permanent magnet 66 is further behind the position of the magnetic stripe MS provided on the recording medium T. Arranged on the side.
When a booklet-type recording medium T such as a passbook is inserted from the manual feed port 15 of the dot impact printer 10, it is conveyed by the sheet conveying mechanism 100 to the position of the recording head 18, and an image is recorded by the recording head 18. Then, the sheet is again discharged from the manual feed port 15 by the sheet conveying mechanism 100. A booklet-type recording medium T such as a passbook is provided with a magnetic stripe MS (FIG. 1) along the main scanning direction on the rear end side of the recording medium T. According to this, even if the rear end of the recording medium T is conveyed until it is positioned below the recording head 18, the permanent magnet 66 is out of the area where the magnetic recording unit MS of the booklet type recording medium T is conveyed. Therefore, the magnetic recording unit MS is prevented from passing over the permanent magnet 66. Therefore, contact or proximity between the permanent magnet 66 and the magnetic recording unit MS can be prevented, and the permanent magnet 66 can prevent destruction of magnetic information written in the magnetic recording unit MS, which affects the magnetic recording unit MS of the recording medium T. Since the influence can be prevented, it is possible to prevent the reading error of the magnetic recording unit MS included in the booklet type recording medium T.

A sheet trailing edge sensor 47 that detects the presence or absence of the recording medium S in the conveyance path of the recording medium S is installed in the vicinity of the alignment plate 28. The sheet trailing edge sensor 47 is formed of a reflection type optical sensor or a transmission type optical sensor, and completes the insertion of the recording medium S from the manual feed port 15 and the ejection of the recording medium S from the printer main body 11. To detect.
Further, the back scanner 112 is disposed between the third drive roller 124A and the fourth drive roller 125A, and the front scanner 111 is disposed at a position facing the back scanner 112. These front and back scanners 111 and 112 are optical image sensors that read information printed on the front and back surfaces of the sheet-type recording medium S, and record, for example, white visible light output from fluorescent tubes or LEDs. An irradiation unit for irradiating the reading area of the medium S, a plurality of light receiving sensors arranged in a line in the main scanning direction (X direction), and an output for outputting signals from the light receiving sensors to the gate array 45 in a predetermined order. Part.

FIG. 5 is a block diagram illustrating a functional configuration of the dot impact printer 10.
The dot impact printer 10 includes a CPU 40 that controls the entire dot impact printer 10 based on a control program, an EEPROM 42 that stores a control program executed by the CPU 40, data to be processed, and the like, and is read from the EEPROM 42 by the CPU 40. A RAM 41 that temporarily stores a control program, data, and the like, and an I / F (Interface) 43 that converts a data format when transmitting / receiving information between the host (computer) 200 that controls the dot impact printer 10 are provided. ing.
The CPU 40 is connected to the recording head 18, the magnetic head 34, and the MICR magnetic head 65 via a gate array (G / A) 45. The gate array 45 outputs a drive current to the recording head 18 according to the control of the CPU 40, and causes the recording wire to protrude. Further, the gate array 45 outputs a read current to the magnetic head 34 or the MICR magnetic head 65 when reading magnetic information according to the control of the CPU 40, while a signal input from the magnetic head 34 or the MICR magnetic head 65. The current is digitized and output to the CPU 40.

  In addition, the sheet rear end sensor 47, the front surface scanner 111, and the back surface scanner 112 are connected to the gate array 45. The sheet rear end sensor 47 is installed in the vicinity of the alignment plate 28 as described above, and is a sensor for detecting the rear end position of the recording medium S or the recording medium T. The sheet rear end sensor 47 operates by the drive current input from the gate array 45. Thus, an analog voltage corresponding to the detected value is output to the gate array 45. The gate array 45 quantizes the analog voltage input from the sheet trailing edge sensor 47 to generate digital data, which is output to the CPU 40.

  The surface scanner 111 reads the information printed on the surface of the recording medium S (the surface opposite to the surface on which MICR information is printed) and supplies the information to the gate array 45. The back scanner 112 reads the information printed on the back of the recording medium S (the surface on which the MICR information is printed) and supplies it to the gate array 45. The gate array 45 quantizes the analog voltage supplied from the front surface scanner 111 and the back surface scanner 112 and outputs the quantized digital data to the CPU 40.

  Further, a motor driver 48 is connected to the gate array 45. The motor driver 48 is connected to the sheet conveyance motor 26, the carriage drive motor 56, and the alignment plate drive motor 64, and supplies these motors with drive current and drive pulses to operate these motors.

  The CPU 40 controls the recording head 18 and the motor driver 48 via the gate array 45 based on the control program stored in the EEPROM 42 and acquires the detection result of the sheet trailing edge sensor 47. Then, the CPU 40 drives the sheet conveying motor 26 to convey the recording medium S or the recording medium T in the sub-scanning direction indicated by the symbol Y, and drives the carriage driving motor 56 to drive the carriage 19 in the main scanning direction indicated by the symbol X. And the alignment plate drive motor 64 is driven to project into the conveyance path P of the alignment plate 28. Further, the CPU 40 controls the gate array 45 to drive the recording head 18 to project the recording wire, or to perform magnetic information processing by the magnetic head 34 or the MICR magnetic head 65.

Next, the reading operation of MICR information by the dot impact printer 10 will be described. FIG. 6 is a flowchart showing an operation procedure for reading the MICR information of the check and ejecting the check when a check is inserted as the recording medium S.
When a sheet-type recording medium S such as a check is inserted from the manual feed slot 15 shown in FIG. 1, the recording medium S is sandwiched between the first driving roller 22A and the first driven roller 22B and before the platen 21. It is conveyed in the direction of arrow A.
At this time, in order to correct the inclination (skew) in the conveyance direction of the recording medium S, the alignment plate 28 protrudes into the conveyance path P of the recording medium S, and the recording medium S is further conveyed while being in contact with the alignment plate 28. Thus, the inclination of the recording medium S is corrected and aligned.
The CPU 40 drives the alignment plate drive motor 64 so as to retract the alignment plate 28 from the conveyance path P, and conveys the recording medium S to a position where the MICR information can be read by the MICR magnetic head 65 (step S1).
Subsequently, when the recording medium S is transported to the MICR information reading start position, the CPU 40 starts reading the MICR information by the MICR magnetic head 65 (step S2). Specifically, the CPU 40 controls the gate array 45 to output a reading current to the MICR magnetic head 65, while receiving a signal current output from the MICR magnetic head 65 through the gate array 45. Whether or not the recording medium S has been transported to the MICR information reading start position is determined based on a change in the signal current value sent from the MICR magnetic head 65.

  Subsequently, the CPU 40 determines whether the trailing edge of the recording medium S has been detected by the sheet trailing edge sensor 47 while reading the MICR information with the MICR magnetic head 65 (step S3). As described above, in this configuration, the MICR magnetic head 65 reads the MICR information and detects the trailing edge of the recording medium S in parallel, thereby improving throughput and shortening the processing time. it can. If the trailing edge is not detected by this determination (step S3; No), the conveyance process of the recording medium S is repeatedly executed until it is detected. If the trailing edge is detected (step S3; Yes), The CPU 40 calculates the paper feed amount (conveyance amount) up to the MICR information reading end position (step S4). In the present embodiment, the MICR magnetic head 65 is fixedly disposed between the second drive roller 23A and the third drive roller 124A. For this reason, if the position of the MICR magnetic head 65 and the size of the area MA provided on the recording medium S are known, the rear end of the area MA (that is, the reading end position) determines the MICR magnetic head 65 based on these positions. A paper feed amount sufficient to pass can be calculated.

Subsequently, the CPU 40 determines whether or not the sheet conveying motor 26 has been driven by the number of steps corresponding to the paper feed amount (step S5). In this determination, if the sheet conveying motor 26 has not been driven by the number of steps corresponding to the paper feed amount (step S5; No), the driving of the sheet conveying motor 26 is continued until the number of steps is reached. When driven by the number of steps (step S5; Yes), the CPU 40 determines whether or not the MICR information has been successfully read (step S6).
Specifically, when the signal current received from the MICR magnetic head 65 through the gate array 45 satisfies a predetermined current pattern, the CPU 40 has succeeded in reading the MICR information corresponding to this signal current. To do. If the CPU 40 has not successfully read the MICR information (step S6; No), the CPU 40 drives the sheet conveying motor 26 in the reverse direction to eject the recording medium S from the manual feed slot 15 (step S7). .
On the other hand, when the MICR information has been successfully read (step S6; Yes), the CPU 40 drives the sheet conveying motor 26 in the forward rotation direction to discharge the recording medium S from the discharge port 8 (step S8). The process is terminated. Note that the CPU 40 transmits information regarding whether or not the MICR information has been successfully read to the host 200 through the I / F 43.

As described above, when the MICR information is successfully read by the MICR magnetic head 65, the sheet-type recording medium S is discharged from a different discharge port from the case where the MICR information reading fails. For this reason, for example, all of the recording media S discharged from the discharge port 8 have been successfully read by the MICR magnetic head 65, and by collecting only the discharges from the discharge port 8, the recording medium S of the host 200 It is possible to reliably and easily determine whether or not the MICR information has been successfully read without checking the display screens one by one.
Further, in this configuration, as shown in FIG. 4, the MICR magnetic head 65 is disposed at a position closer to the discharge port 8 than the manual feed port 15. According to this, when the MICR information is successfully read, the transport distance and the transport time can be shortened by discharging the recording medium S from the discharge port 8 on the side closer to the MICR magnetic head 65. The processing capacity per unit time can be improved.
Further, the recording medium S that has failed to read the MICR information by the MICR magnetic head 65 is ejected from the manual feed slot 15. The dot impact printer 10 of the present embodiment is disposed at a financial institution's window. When reading MICR information, the user directly applies the dot impact from the manual feed slot 15 to the recording medium S (check). It is often inserted into the printer 10. For this reason, by ejecting the recording medium S that has failed to read the MICR information from the manual slot 15, the user can easily know that the MICR information has failed to be read. The failed recording medium S can be easily read again.

  As described above, according to the present embodiment, a booklet type recording medium having a magnetic stripe and a sheet type recording medium S on which MICR information is recorded can be transported. In the dot impact printer 10 that records an image on a sheet-type recording medium S, a plurality of rows of first driving rollers 22A, second driving rollers 23A arranged in the conveying direction of the booklet-type recording medium T and the sheet-type recording medium S, A sheet conveyance mechanism 100 having a third drive roller 124A and a fourth drive roller 125A, a magnetic head 34 for reading the magnetic stripe MS of the booklet-type recording medium T, a second drive roller 23A, and a third drive roller 124A. And a MICR magnetic head 65 for reading the MICR information recorded on the sheet type recording medium S. The sheet conveying mechanism 100 can eject the recording medium S in at least two different directions. When the MICR information is successfully read by the MICR magnetic head 65, the sheet conveying mechanism 100 is ejected from a different outlet than when the MICR information is unsuccessfully read. The sheet type recording medium S is discharged. For this reason, for example, all of the recording media S discharged from the discharge port 8 have been successfully read by the MICR magnetic head 65, and by collecting only the discharges from the discharge port 8, the recording medium S of the host 200 It is possible to reliably and easily determine whether or not the MICR information has been successfully read without checking the display screens one by one.

  Further, according to the present embodiment, when the MICR magnetic head 65 succeeds in reading the MICR information, the sheet conveying mechanism 100 removes the sheet type recording medium S from the discharge port 8 on the side closer to the MICR magnetic head 65. Since the paper is discharged, the transport distance and the transport time can be shortened, and the processing capacity per unit time can be improved.

  Further, according to the present embodiment, when the MICR information is successfully read by the MICR magnetic head 65, the sheet is ejected in a different ejection direction from the case where the MICR information reading is unsuccessful and the case where the booklet-type recording medium is ejected. Whether or not the MICR information has been successfully read without confirming the display screen of the host 200 one by one by collecting only those discharged from the discharge port 8 in the discharge direction in order to discharge the recording medium S of the type. Can be determined reliably and easily.

  Further, according to the present embodiment, the permanent magnet 66 that magnetizes the magnetic ink characters constituting the MICR information is provided at a position outside the area where the magnetic stripe MS of the booklet type recording medium T is conveyed. The magnetic recording unit MS is prevented from passing over the permanent magnet 66. Therefore, contact or proximity between the permanent magnet 66 and the magnetic recording unit MS is prevented, and the permanent magnet 66 can prevent the magnetic information written in the magnetic recording unit MS from being destroyed, which affects the magnetic recording unit MS of the recording medium T. Since the influence can be prevented, it is possible to prevent the reading error of the magnetic recording unit MS included in the booklet type recording medium T.

Although one embodiment of the present invention has been described above, the present invention is not limited to this. For example, in this embodiment, when the MICR information is successfully read, the MICR information is discharged from the discharge port 8 provided at the rear of the dot impact printer 10. The configuration for discharging from the provided manual feed port 15 has been described. However, if the reading is successful, it may be discharged in a different direction from the case where the reading is unsuccessful. May be changed. Further, when reading fails, the recording medium may not be discharged from the manual feed port 15 but a separate discharge port may be provided. According to this configuration, it is possible to easily read MICR information on a plurality of recording media.
Further, the present invention is not limited to a dot impact type printer, but can also be applied to an ink jet type printer or a thermal printer that records an image by heating a thermal medium.

  DESCRIPTION OF SYMBOLS 8 ... Discharge port, 10 ... Dot impact printer (recording apparatus), 11 ... Printer main body, 15 ... Manual feed port, 18 ... Recording head, 19 ... Carriage, 22A ... 1st drive roller (conveyance roller), 23A ... 2nd Drive roller (conveyance roller), 34 ... magnetic head (first magnetic head), 40 ... CPU, 47 ... sheet trailing edge sensor, 65 ... MICR magnetic head (second magnetic head), 66 ... permanent magnet (magnetized) Part), 100 ... sheet conveying mechanism, 124A ... third driving roller (conveying roller), 125A ... fourth driving roller (conveying roller), 200 ... host, MA ... area, S ... recording medium.

Claims (4)

A booklet-type recording medium having a magnetic recording unit and a sheet-type recording medium on which MICR information is recorded are configured to be able to be transported, and a recording for recording an image on the booklet-type recording medium and the sheet-type recording medium In the device
A transport mechanism having a plurality of rows of transport rollers arranged in the transport direction of the booklet-type recording medium and the sheet-type recording medium, a first magnetic head for reading a magnetic recording unit of the booklet-type recording medium, A second magnetic head that is arranged between the plurality of rows of conveyance rollers and reads MICR information recorded on the sheet-type recording medium, and the conveyance mechanism moves the recording medium in at least two different directions. The sheet-type recording medium is ejected in a different ejection direction from that in the case where the MICR information reading by the second magnetic head is successful and when the MICR information reading is unsuccessful. Recording device.   The transport mechanism discharges the sheet-type recording medium from a discharge port closer to the second magnetic head when the reading of MICR information by the second magnetic head is successful. The recording apparatus according to claim 1.   When the reading of the MICR information by the second magnetic head is successful, the sheet-type recording medium has a different ejection direction than when the reading of the MICR information fails and when the booklet-type recording medium is ejected. The recording apparatus according to claim 1, wherein the recording device is discharged.   The magnetized portion for magnetizing the magnetic ink characters constituting the MICR information is provided at a position outside a region where the magnetic recording portion of the booklet type recording medium is conveyed. 4. The recording device according to any one of 3.

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