JP5774653B2 - Printer device - Google Patents

Description

  Embodiments described herein relate generally to a printer device that prints and issues paper.

  In a printer device used as an issuer for receipts or the like, after printing predetermined items on a long sheet drawn from a roll wound paper, the paper is cut into a predetermined length of paper and discharged. Is going.

  When these printer devices are used in a supermarket or the like, since the operator of the printer device is close to the printer device, it is possible to easily replenish paper even if the paper runs out. For this reason, it is not necessary to make the diameter of the paper wound in a roll loaded into the printer device so large. However, there are many cases where there is no operator nearby in a printer device used for ATM or the like. For this reason, in order to reduce the frequency of out of paper, the diameter of the paper wound in the roll shape loaded in the printer apparatus is often increased.

  In order to load the paper into the printer device, a method called loading accommodation, where the paper wound in a roll shape is placed on the paper receiving portion as it is, is taken from the ease of loading the paper. However, the outer periphery of the paper wound in a roll shape may come into contact with the inner wall of the printer device, resulting in a conveyance failure. This is more likely to occur as the diameter of the paper wound in a roll is larger. For this reason, it is known to reduce the coefficient of friction of the inner wall and bottom surface of the printer device that comes into contact with the roll-wrapped paper.

  If the paper wound in a roll shape has a large diameter, it may be difficult to rotate even if it is pulled out by a printing unit that performs printing on the paper. It is also known to place a sheet wound in a roll on a roller having driving force without directly contacting the wall or bottom surface of the sheet. However, when the diameter of the paper wound in the roll shape is large, the weight is large, and a large load is applied at the time of starting the rotation when the paper wound in the roll shape is stopped from rotating. There is a problem that is not transported correctly.

JP 2008-143004 A

  The problem to be solved by the present invention is to provide a printer apparatus that correctly conveys a sheet even in a large load state at the start of rotation in a sheet wound in a roll shape having a large sheet diameter.

In order to solve the above problems, a paper transport path for pulling out and transporting a wound paper, a printing section for performing printing on the paper, and a roller for rotating the paper in contact with the outer peripheral surface of the paper A first motor for applying a driving force to the roller, a second motor capable of applying an auxiliary driving force to the roller, and detecting whether or not the rotation of the roller is in a steady state. And a second motor rotation control means for reducing a current value applied to the second motor when the rotation of the roller is detected to be in a steady state by the steady rotation detection unit. Have .

FIG. 2 is a main part configuration diagram of the printer apparatus according to the first embodiment. FIG. 3 is a main part configuration diagram of a sensor roller unit of the printer device according to the first embodiment. FIG. 3 is a main part configuration diagram of a sensor block unit of the printer apparatus according to the first embodiment. FIG. 3 is a block diagram illustrating a control circuit configuration of the printer apparatus according to the first embodiment. The flowchart which shows the flow of the auxiliary motor drive switching method which concerns on 1st Embodiment. FIG. 10 is a main part configuration diagram of a printer apparatus according to a second embodiment. The flowchart which shows the flow of the auxiliary motor drive switching method which concerns on 2nd Embodiment. FIG. 10 is a configuration diagram of a main part of a printer apparatus according to a third embodiment. The flowchart which shows the flow of the auxiliary motor provision electric current change which concerns on 3rd Embodiment. FIG. 10 is a configuration diagram of a main part of a printer apparatus according to a fourth embodiment. The flowchart which shows the flow of the auxiliary motor provision electric current change which concerns on 4th Embodiment.

(First embodiment)
Hereinafter, a printer apparatus according to a first embodiment of the present embodiment will be described in detail with reference to the drawings.

  FIG. 1 is a configuration diagram illustrating a main part of the printer apparatus 1 according to the first embodiment. In this printer, since the sheet is conveyed from the lower side to the upper side in the figure, in the following description, the lower side in the figure is the upstream side and the upper side is the downstream side.

  In the figure, reference numeral 2 denotes a wound roll paper. For the paper 2, a printer cover (not shown) provided in the printer device 1 is opened, and the paper 2 is loaded into the printer device 1 from above.

  At the time of loading, the sheet 2 is placed in a state where the loading position is regulated by the sheet guide A 3 and the sheet guide B 4 and in contact with the sensor roller 7 and the delivery roller 12.

  The paper 2 has a first paper surface 5 and a second paper surface 6 opposite to the first paper surface 5, and only the first paper surface 5 is a heat-sensitive layer that develops color when heated. Is provided.

  An idler roller 13 is rotatably supported on the downstream side of the feed roller 12.

  Further, a conveyance guide A14 and a conveyance guide B15 are extended from the idler roller 13 of the printer apparatus 1 toward the downstream side of the printer apparatus 1, and a sheet conveyance path 16 is provided between the conveyance guide A14 and the conveyance guide B15. As a result, the sheet 2 is conveyed.

  On the downstream side of the idler roller 13, there are provided a thermal print head 17 and a platen roller 18 that can be rotated by a motor (not shown) across the paper transport path 16 with respect to the thermal print head 17. The print unit 17 is configured by the print head 17 and the platen roller 18, and the print unit 19 performs printing on the first sheet surface 5 of the sheet 2.

  A cutter 20 is disposed on the downstream side of the printing unit 19. The cutter 20 has a fixed blade and a movable blade (not shown), and the cutter motor (not shown) directs the paper 2 inserted in a slit (not shown) provided in the cutter 20 to the fixed blade. Cut by sliding by driving.

  Here, the cutter 20 has been described as a so-called slide type cutter in which the movable blade slides toward the fixed blade. However, the cutter 20 is not limited to this, and a so-called rotary type in which the movable blade rotates relative to the fixed blade to cut the paper. It may be a cutter.

  On the downstream side of the cutter 20, a discharge roller 21 that can be rotated by a motor (not shown), and a discharge idler roller 22 are disposed opposite to the discharge roller 21 with the paper transport path 16 interposed therebetween. Further, the printer apparatus 1 has a paper discharge port 23 on the downstream side of the discharge roller 21, and the paper 2 that has been printed and cut by the cutter 20 is transferred to the paper 2 by the cooperation of the discharge roller 21 and the discharge idler roller 22. The ink is discharged from the discharge port 23 to the outside of the printer apparatus 1.

  Further, the printer device 1 is provided with a display unit 24 for displaying various states including an error state of the printer device 1.

  Further, the printer device 1 is provided with a sensor roller 7, a paper motor 8, and an auxiliary motor 9.

  All of the sensor roller 7, the paper motor 8, and the auxiliary motor 9 are provided with a gear (not shown), and the gear of the sensor roller 7 and the gear of the paper motor 8 are connected. A transmission gear 11 is connected to the gear of the auxiliary motor 9, and a one-way clutch 10 is provided between the transmission gear 11 and the sensor roller 7.

  Next, FIG. 2 and FIG. 3 show the sensor roller 7 and the steady rotation detector. The sensor roller 7 includes a contact roller 30-1 and a shaft 30-2, and a sensor block 26 having a substantially concave shape is provided in the vicinity of the shaft 30-2. A light emitting unit 27 and a light receiving unit 28 are provided on the inner surfaces of the sensor block 26 facing each other, and the sensor block 26, the light emitting unit 27, and the light receiving unit 28 constitute a rotation sensor 25.

  Further, the shaft 30-2 of the sensor roller 7 is disposed between the light emitting unit 27 and the light receiving unit 28. The shaft 30-2 is provided with a through hole 31, through which the detection light 29 passes from the light emitting unit 27 toward the light receiving unit 28.

  The rotation sensor 25, the shaft 30-2 of the sensor roller 7 and the through hole 31 constitute a steady rotation detection unit that detects whether the sensor roller 7 is rotating normally.

  Judgment whether the sensor roller 7 is rotating normally will be described with reference to FIGS.

  The sensor roller 7 has a contact roller 30-1 and a shaft 30-2, and a substantially concave sensor block 26 is provided so as to surround the shaft 30-2 from the side and from below. A light emitting portion 27 is provided on the inner surface of the sensor block 26 on the shaft 30-2 side, and a light receiving portion 28 is provided on the inner surface facing the light emitting portion 27. The detection light 29 emitted from the light emitting portion 27 is received by the light receiving portion. 28 is incident. In the shaft 30-2, a through hole 31 is provided in a portion of the path of the detection light 29 from the light emitting unit 27 to the light receiving unit 28. That is, the detection light 29 emitted from the light emitting unit 27 passes through the through hole 31 and reaches the light receiving unit 28 in the state of the shaft 30-2 shown in FIG. It is blocked and does not reach the light receiving unit 28.

  The control unit 51 instructs the light emitting unit 27 of the rotation sensor 25 to always emit light, and receives a signal when the light receiving unit 28 receives the detection light 29.

  The rotation speed of the sensor roller 7 in a steady state is determined in advance. When the sensor roller 7 rotates in a steady state, the light receiving unit 28 outputs a light reception signal at a predetermined time interval. By checking this signal, the control unit 51 can determine whether the sensor roller 7 is rotating in a steady state.

  The sensor roller 7 is provided with a plurality of contact rollers 30-1. The surface of the contact roller 30-1 is made of a material such as rubber and is in contact with the surface of the roll-shaped paper 2. Therefore, when the sensor roller 7 rotates in the X direction, the roll-shaped paper 2 that is in contact with the sensor roller 7 rotates in the Y direction. The steady rotation speed of the sensor roller 7 is set so as to correspond to the normal conveyance speed of the paper 2. Therefore, the determination as to whether the sensor roller 7 is rotating in a steady state determines whether the sheet 2 is being conveyed at a normal conveyance speed.

  FIG. 4 is a block diagram illustrating a control circuit configuration of the printer apparatus 1 according to the present embodiment. The control unit 51 performs control of paper conveyance, printing, paper cutting, paper discharge, and printer status display.

  The control unit 51 is composed of, for example, a microcomputer that links with the host computer 50 and executes various controls. A central processing unit (MPU) 52 of the control unit 51 performs various controls and calculations such as paper conveyance control, printing control, paper cutting control, and paper discharge control according to a program.

  The MPU 52 includes a timer 53 as means for performing time setting and time control.

Further, the control unit 51 is provided with a ROM 54 and a RAM 55 as main storage means for storing a control program executed by the MPU 52, data in the process of control or calculation, and the like.
The ROM 54 is a read-only memory having a control program, a table, and the like, and the RAM 55 is an occasional write memory that stores data in the middle of calculation.

  Further, the control unit 51 is provided with an input / output unit (I / O) 56 for taking in various input data from the host computer 50 and taking out the control output of the control unit 51 to the host computer 50. . The I / O 56 is connected to the MPU 52, the ROM 54, and the RAM 55 through a bus.

  Further, the I / O 56 has first, second, third, fourth, fifth, sixth and seventh drivers 57, 58, 59, 60, 61, 62 as means for taking out the control output. 63 is connected.

  The first driver 57 supplies a necessary drive output to the printing unit 19. The second driver 58 supplies a necessary drive output to the paper motor 8. The third driver 59 supplies a necessary drive output to the auxiliary motor 9. The fourth driver 60 supplies a drive output to the cutter 20. The fifth driver 61 supplies a drive output to the discharge roller 21. The sixth driver 62 supplies a display drive output for causing the display unit 24 to perform various displays. The seventh driver 63 supplies a drive signal to the rotation sensor 25.

  When printing is performed on the paper 2 by the printing unit 19, the platen roller 18 is rotationally driven by the motor in synchronization with the printing operation based on the control output as the print command means of the MPU 52. The thermal print head 17 generates heat based on print data from the host computer 50 and prints on the first surface 5 of the paper 2.

  The MPU 52 of the control unit 51 rotates and stops the paper motor 8 via the driver 58.

  The MPU 52 of the controller 51 rotates and stops the auxiliary motor 9 via the driver 59.

  The MPU 52 of the control unit 51 drives the cutter 20 via the driver 60 to cut the paper 2.

  The MPU 52 of the control unit 51 rotates and stops the discharge roller 21 via the driver 61.

  The MPU 52 of the control unit 51 displays various information, errors, and the like of the printer device 1 on the display unit 24 via the driver 62.

  The MPU 52 of the control unit 51 drives the rotation sensor 25 via the driver 63 and receives a detection signal.

  Hereinafter, the operation of the printer apparatus 1 will be described with reference to FIGS. 1 to 3 and FIG. The control unit 51 performs paper conveyance and printing operations according to a program stored in the ROM 54.

  First, the operator opens a printer cover (not shown) provided in the printer apparatus 1 and loads the wound roll-shaped paper 2 into the printer apparatus 1 from above. At the time of loading, the sheet 2 is placed in a state where the loading position is regulated by the sheet guide A 3 and the sheet guide B 4 and in contact with the sensor roller 7 and the delivery roller 12.

  Next, the paper 2 is pulled out, and after passing through the idler roller 13, the leading edge of the paper 2 is set so as to be positioned between the thermal printing head 17 and the platen roller 18.

  In this state, when print data is received from the host computer 50 (S1), the control unit 51 determines whether the sensor roller 7 is rotating normally (S2).

  When it is determined that the sensor roller 7 does not rotate at regular speed (N in S2), the control unit 51 sends a drive signal to the auxiliary motor 9 so that the drive signal is turned on. Is rotated (S3). When the drive signal is already ON when sending the drive signal to the auxiliary motor 9, the auxiliary motor 9 is kept in the ON state.

  The auxiliary motor 9 and the sensor roller 7 are each provided with a gear (not shown). A transmission gear 11 is connected to the gear of the auxiliary motor 9, and a one-way clutch 10 is provided between the transmission gear 11 and the sensor roller 7. The one-way clutch 10 transmits the rotational force only in the direction in which the rotation of the transmission gear 11 is transmitted to the gear of the sensor roller 7. Therefore, when the auxiliary motor 9 receives the drive signal, the rotation is transmitted to the sensor roller 7 via the transmission gear 11 and the one-way clutch 10 to rotate the sensor roller 7.

  The rolled roll-shaped paper 2 is placed on the sensor roller 7 and the feed roller 12 having no driving force. Since the rotational force of the auxiliary motor 9 becomes a force that rotates the sensor roller 7 in the X direction in FIG. 1, the rotational force in the Y direction is applied to the paper 2 by friction with the contact roller 30-1 of the sensor roller 7. Is done.

  Next, the control unit 51 drives the printing unit 19 to start printing the print data received from the host computer 50 on the first paper surface 5 of the paper 2 (S4). In printing, the platen roller 18 is rotated and the thermal print head 17 is driven. At the same time, the paper motor 8 is driven.

  The paper motor 8 is connected to a gear (not shown) of the sensor roller 7 and rotates in the Z direction in FIG. 1, and thus rotates the sensor roller 7 in the X direction. Therefore, a rotational force in the Y direction is applied to the sheet 2 by friction between the sensor roller 7 and the contact roller 30-1.

  That is, both the driving force due to the rotation of the auxiliary motor 9 and the driving force due to the rotation of the paper motor 8 are transmitted to the sensor roller 7. In a state where the roll diameter of the paper 2 is large, rotation starts from a state in which the paper 2 is stopped, and then a large load is required to reach steady rotation, and it may be difficult to rotate the sensor roller 7 with the paper motor 8 alone. is there.

  However, as described above, when the sensor roller 7 is not rotating regularly, the auxiliary motor 9 is driven to transmit the driving force to the sensor roller 7. As a result, it is possible to correctly convey the sheet 2 even when a large load is applied at the time of startup when the roll diameter of the sheet 2 is large.

  The controller 51 performs printing by the rotation of the printing roller 19 and the sensor roller 7 driven by both the paper motor 8 and the auxiliary motor 9, and then the printing is performed every predetermined time or every predetermined amount of data. It is confirmed whether it is completed (S5). If printing is completed (Y in S5), printing ends (S6). If printing has not been completed (N in S5), it is determined again whether the rotation is in a steady state (S2).

  In this way, printing is performed by driving the sensor roller 7 by driving both the paper motor 8 and the auxiliary motor 9 until it is recognized as rotating in a steady state.

  In the middle of printing, the control unit 51 checks whether printing is completed for every predetermined time or printing for a predetermined amount of data (S5). If printing has not ended (S5) N) again determines whether it is rotating in a steady state (S2), but if it is determined here that it is rotating in a steady state (Y in S2), the transmission of the drive signal to the auxiliary motor 9 is stopped, The driving of the auxiliary motor 9 is stopped (S7). Whether or not the light is rotating in the steady state is determined based on whether or not the signal when the light receiving unit 28 receives light is output at the time interval when rotating in the steady state as described above.

  When the roll-shaped paper 2 has a large roll diameter, a large load is applied at the time of starting to move from the stop state, and therefore it is difficult to rotate the sensor roller 7 with only the driving force of the paper motor 8. There is. However, after steady rotation by driving both the auxiliary motor 9 and the paper motor 8 at the time of starting, the load as at the time of starting is not applied, and even if the sensor roller 7 is driven only by the driving force of the paper motor 8, the sensor roller It is possible to maintain a steady rotation of 7.

  When the driving of the auxiliary motor 9 is stopped, the gear (not shown) provided in the auxiliary motor 9 and the transmission gear 11 connected thereto are also stopped. Stopping the transmission gear 11 in a state where the transmission gear 11 and the sensor roller 7 are simply connected results in a load on the rotation of the sensor roller 7. However, a one-way clutch 10 is provided between the transmission gear 11 and the sensor roller 7. As a result, even if the transmission gear 11 stops, the sensor roller 7 that has received the driving force of the paper motor 8 continues to rotate. Therefore, the transmission gear in which the rotational force of the sensor roller 7 is stopped by the action of the one-way clutch 10 thereafter. 11 is not transmitted.

  Since the auxiliary motor 9 is stopped, the control unit 51 performs printing by the rotation of the sensor roller 7 driven by the printing unit 19 and the paper motor 8 (S8). Thereafter, it is confirmed whether or not printing is completed after elapse of a predetermined time or after printing of a predetermined amount of data (S9). If printing is completed here (Y in S9), printing ends (S10). If printing has not been completed (N in S9), it is determined again whether the rotation is in a steady state (S2).

  As described above, it is determined whether or not the sheet 2 is being conveyed correctly by detecting whether the sensor roller 7 is rotating normally. When the sensor roller 7 does not rotate at a constant speed, for example, when the roll diameter of the sheet 2 is large and the load at the time of start-up is large, the auxiliary motor 9 is driven and driven by both the paper motor 8. When the sensor roller 7 is rotating in a steady state, the load is not as high as that at the time of activation, so that the auxiliary motor 9 is not driven and only the paper motor 8 is driven. By stopping the auxiliary motor 9, the power consumption of the printer apparatus 1 is reduced. Further, the noise caused by the rotation of the auxiliary motor 9 is also reduced.

  The one-way clutch 10 is interposed in the driving force transmission path between the auxiliary motor 9 and the sensor roller 7. After the auxiliary motor 9 stops, the driving force transmitted from the auxiliary motor 9 to the sensor roller 7 is transmitted to the one-way clutch 10. Blocked by work. Thereby, the auxiliary motor 9 does not become a load of rotation of the sensor roller 7.

  In addition, a steady rotation detection unit that detects whether the roll-shaped paper 2 is rotating regularly is provided in a direction A that is upstream of the sheet conveyance direction from a vertical line passing through the center of the roll-shaped paper 2.

  Since the paper 2 is only placed on the sensor roller 7 and the delivery roller 12, when the paper 2 is pulled out by the thermal print head 17 and the platen roller 18, the paper is drawn from a vertical line passing through the center of the roll-like paper 2. It becomes easy to move in the direction A which is the upstream side in the transport direction. If the detection position of the steady rotation detection unit exists in the moving direction like the sensor roller 7 in FIG. 1, the contact between the roll-shaped paper 2 and the sensor roller 7 is easily maintained, and the detection accuracy is high. Become. However, if the detection position of the steady rotation detection unit exists in the direction opposite to the moving direction, which is the position of the feed roller 12 in FIG. 1, the roll-shaped paper 2 is moved by the movement of the roll-shaped paper 2. There is a possibility that the contact between the sensor roller 7 and the sensor roller 7 is separated, and the detection accuracy is lowered. As described above, it is desirable that the sensor roller 7 and the steady rotation detecting unit for detecting whether or not the roll-shaped paper 2 is normally rotated be provided on the upstream side in the paper conveyance direction from the vertical line passing through the center of the roll-shaped paper 2. .

  In addition to the detection of the rotation of the sensor roller 7 as described above, the steady rotation detection unit may directly detect the conveyance state of the sheet and determine whether the sheet is normally conveyed. In this case, for example, a black mark is provided on the second sheet surface 6 of the sheet, and this black mark is read by a reflection type sensor (not shown), and it can be determined whether the sheet is normally conveyed based on the read result.

(Second Embodiment)
Hereinafter, the printer device 1 according to the second embodiment of the present embodiment will be described with reference to FIGS. 6 and 7. In addition, the same code | symbol is attached | subjected in the same component as 1st Embodiment, and the detailed description is abbreviate | omitted.

  In the second embodiment, instead of detecting the steady rotation of the roll-shaped paper 2 and determining whether the auxiliary motor 9 needs to be driven based on the result, the remaining amount of the roll-shaped paper 2 is determined. It is detected and the necessity of driving the auxiliary motor 9 is determined based on the result.

  A paper sensor 32 is fixedly installed on a frame (not shown) of the printer apparatus 1. Each of the paper sensors 32 has a light emitting unit and a light receiving unit (not shown), and detection light (not shown) emitted from the light emitting unit is detected by the light receiving unit. The height of the detection light is H. A roll-shaped sheet 2 exists between the light emitting unit and the light receiving unit.

  When the detection light emitted from the light emitting unit reaches the light receiving unit, the arrival of the detection light is blocked if the roll-shaped paper 2 exists between them. For this reason, it is possible to detect whether the roll diameter has become smaller than a predetermined size. For example, when the diameter of the roll-shaped paper 2 is 2-F, which is the size at the time of loading, or when the paper 2 is used and the diameter of the roll-shaped paper 2 is about half that at the time of loading 2- In the case of M, since the sheet 2 exists between the light emitting unit and the light receiving unit, the detection light emitted from the light emitting unit is blocked from reaching the light receiving unit. Therefore, no light reception signal is generated from the light receiving unit.

  However, in the case of 2-E, in which the sheet 2 is used and the diameter of the roll-shaped sheet 2 is about a quarter of that at the time of loading, the sheet 2 exists between the light emitting unit and the light receiving unit. Therefore, the detection light emitted from the light emitting unit reaches the light receiving unit. For this reason, a light receiving signal is emitted from the light receiving unit. The sheet sensor 32 having the light emitting section and the light receiving section serves as a remaining sheet detecting section.

  In order to determine whether or not the auxiliary motor 9 needs to be driven using the detection result of the remaining paper amount detection unit, the rotation sensor 25 and the through hole 31 that are the steady rotation detection unit described in the first embodiment are provided. Not.

  The ROM 54 is set to stop the drive signal to the auxiliary motor 9 when the diameter of the roll-shaped paper 2 is smaller than 2-E.

  The driving of the auxiliary motor 9 of the second embodiment will be described with reference to FIG.

  As in the first embodiment, when print data is received from the host computer 50 with the paper 2 set in the printer device 1 (S11), the control unit 51 receives the paper loaded in the printer device 1. It is determined whether the remaining amount of 2 is large (S12).

  As shown in FIG. 6 described above, the remaining amount of the sheet 2 is determined based on whether or not the diameter of the roll-shaped sheet 2 is less than the diameter of 2-E.

  When it is determined that the remaining amount of the sheet 2 is large (Y in S12), the light receiving unit of the sheet sensor 32 does not receive the detection light and the light reception signal is not output, that is, the diameter of the roll-shaped sheet 2 is larger than 2-E. Since the roll diameter of the sheet 2 is large and a large load is applied at the time of start-up, there is a possibility that the sheet 2 cannot be conveyed correctly only by the paper motor 8. Therefore, the control unit 51 assists the auxiliary motor 9. A drive signal is sent so that the motor 9 is turned on, and the auxiliary motor 9 is rotated (S13). When the drive signal is already ON when sending the drive signal to the auxiliary motor 9, the auxiliary motor 9 is kept in the ON state.

  Next, the control unit 51 drives the printing unit 19 to start printing the print data received from the host computer 50 on the first sheet surface 5 of the sheet 2 (S14). In printing, the platen roller 18 is rotated and the thermal print head 17 is driven. At the same time, the paper motor 8 is driven.

  The paper motor 8 is connected to a gear (not shown) of the sensor roller 7 and rotates in the Z direction in FIG. 6, and thus rotates the sensor roller 7 in the X direction. Therefore, a rotational force in the Y direction is applied to the sheet 2 by friction between the sensor roller 7 and the contact roller 30-1.

  That is, both the driving force due to the rotation of the auxiliary motor 9 and the driving force due to the rotation of the paper motor 8 are transmitted to the sensor roller 7. When the remaining amount of the paper 2 is large, the rotation is started from the state where the paper 2 is stopped, and then a large load is required to reach the steady rotation, and it is difficult to rotate the sensor roller 7 with the paper motor 8 alone. is there.

  However, as described above, when the remaining amount of the sheet 2 is large, the auxiliary motor 9 is driven to transmit the driving force to the sensor roller 7. As a result, it is possible to correctly convey the sheet 2 even when a large load is applied at the time of startup when the roll diameter of the sheet 2 is large.

  The controller 51 performs printing by the rotation of the printing roller 19 and the sensor roller 7 driven by both the paper motor 8 and the auxiliary motor 9, and then the printing is performed every predetermined time or every predetermined amount of data. It is confirmed whether it is completed (S15). If printing is completed here (Y in S15), printing ends (S16). If printing has not been completed (N in S15), it is determined whether the remaining amount of paper 2 is large (S12).

  In this way, printing is performed by driving the sensor roller 7 by driving both the paper motor 8 and the auxiliary motor 9 until it is recognized that the remaining amount of the sheet 2 is not large.

  In the middle of printing, the control unit 51 checks whether printing is completed for every predetermined time or printing for a predetermined amount of data (S15). If printing has not been completed (S15) N) again determines whether the remaining amount of the sheet 2 is large (S12). If it is determined here that the remaining amount of the sheet 2 is not large (N in S12), a drive signal is transmitted to the auxiliary motor 9. The driving of the auxiliary motor 9 is stopped (S17). The determination that the remaining amount of the sheet 2 is not large is made based on whether or not the diameter of the sheet 2 is smaller than the position of the predetermined point H as described above.

Rolled sheets 2, in its roll diameter is large state, in order that under heavy load during movement is started from a stopped state, it is only the driving force of Pepamota 8 to steady rotation sensor roller 7 is difficult There may be. However, after steady rotation by driving both the auxiliary motor 9 and the paper motor 8 at the time of starting, the load as at the time of starting is not applied, and even if the sensor roller 7 is driven only by the driving force of the paper motor 8, the sensor roller It is possible to maintain a steady rotation of 7.

  When the driving of the auxiliary motor 9 is stopped, the gear (not shown) provided in the auxiliary motor 9 and the transmission gear 11 connected thereto are also stopped. Stopping the transmission gear 11 in a state where the transmission gear 11 and the sensor roller 7 are simply connected results in a load on the rotation of the sensor roller 7. However, a one-way clutch 10 is provided between the transmission gear 11 and the sensor roller 7. As a result, even if the transmission gear 11 stops, the sensor roller 7 that has received the driving force of the paper motor 8 continues to rotate. Therefore, the transmission gear in which the rotational force of the sensor roller 7 is stopped by the action of the one-way clutch 10 thereafter. 11 is not transmitted.

  Since the auxiliary motor 9 is stopped, the control unit 51 performs printing by the rotation of the sensor roller 7 driven by the printing unit 19 and the paper motor 8 (S18). Thereafter, it is confirmed whether or not printing is completed after elapse of a predetermined time or after printing of a predetermined amount of data (S19). If printing is completed (Y in S19), printing ends (S20). If printing has not been completed (N in S19), it is determined again whether the remaining amount of the sheet 2 is large (S12).

  As described above, it is determined whether the remaining amount of the sheet 2 is large. When the remaining amount of the sheet 2 is large, for example, when the load at the time of activation is large, the auxiliary motor 9 is driven and driven by both the paper motor 8. When the remaining amount of the sheet 2 is small, the remaining amount of the sheet 2 is small, so that the auxiliary motor 9 is not driven even at the time of start-up, and the sheet 2 can be normally conveyed even when driven by the paper motor 8 alone. is there. By stopping the auxiliary motor 9, the power consumption of the printer apparatus 1 is reduced. Further, the noise caused by the rotation of the auxiliary motor 9 is also reduced.

  The one-way clutch 10 is interposed in the driving force transmission path between the auxiliary motor 9 and the sensor roller 7. After the auxiliary motor 9 stops, the driving force transmitted from the auxiliary motor 9 to the sensor roller 7 is transmitted to the one-way clutch 10. Blocked by work. Thereby, the auxiliary motor 9 does not become a load of rotation of the sensor roller 7.

(Third embodiment)
Hereinafter, a printer device 1 according to a third embodiment of the present embodiment will be described with reference to FIGS. 8 and 9. In addition, the same code | symbol is attached | subjected in the same component as 1st Embodiment, and the detailed description is abbreviate | omitted.

  In the third embodiment, instead of detecting the steady rotation of the roll-shaped paper 2 and determining whether or not the auxiliary motor 9 needs to be driven based on the result, the auxiliary motor 9 is determined based on the detection result. The current value to be applied is changed.

  Moreover, the drive of the auxiliary motor 9 is not stopped in any result of the detection result as to whether or not the paper 2 is rotating at a constant only by changing the current value. For this reason, the one-way clutch that is interposed between the auxiliary motor 9 and the sensor roller 7 provided in the first embodiment is not provided.

  The method for detecting whether or not the sensor roller 7 is in a steady state is the same as in the first embodiment, and thus detailed description thereof is omitted.

  The driving of the auxiliary motor 9 of the third embodiment will be described with reference to FIG.

  As in the first embodiment, when the print data is received from the host computer 50 with the paper 2 set in the printer apparatus 1 (S21), the control unit 51 determines whether the sensor roller 7 is rotating normally. Is determined (S22).

  As shown in FIG. 6 described above, the remaining amount of the sheet 2 is determined based on whether or not the diameter of the roll-shaped sheet 2 is less than the diameter of 2-E.

  When it is determined that the sensor roller 7 does not rotate normally (N in S22), when the roll diameter of the paper 2 is large and a large load is applied at the time of start-up, there is a possibility that the paper 2 cannot be conveyed correctly only with the paper motor 8. Therefore, the control unit 51 sends a drive signal to the auxiliary motor 9 so that the auxiliary motor 9 is turned on, and rotates the auxiliary motor 9 (S23).

  At this time, the current applied to the auxiliary motor 9 is a current value at which the maximum torque of the auxiliary motor 9 is obtained. Further, when the drive signal is already ON when sending the drive signal to the auxiliary motor 9, the current applied to the auxiliary motor 9 is not changed and the ON state is continued.

  Next, the control unit 51 drives the printing unit 19 to start printing the print data received from the host computer 50 on the first paper surface 5 of the paper 2 (S24). In printing, the platen roller 18 is rotated and the thermal print head 17 is driven. At the same time, the paper motor 8 is driven.

  The paper motor 8 is connected to a gear (not shown) of the sensor roller 7 and rotates in the Z direction in FIG. 8, and thus rotates the sensor roller 7 in the X direction. Therefore, a rotational force in the Y direction is applied to the sheet 2 by friction between the sensor roller 7 and the contact roller 30-1.

  That is, both the driving force due to the rotation of the auxiliary motor 9 and the driving force due to the rotation of the paper motor 8 are transmitted to the sensor roller 7. When the remaining amount of the paper 2 is large, the rotation is started from the state where the paper 2 is stopped, and then a large load is required to reach the steady rotation, and it is difficult to rotate the sensor roller 7 with the paper motor 8 alone. is there.

  However, as described above, when the sensor roller 7 is not rotating regularly, the auxiliary motor 9 is driven to transmit the driving force to the sensor roller 7. As a result, it is possible to correctly convey the sheet 2 even when a large load is applied at the time of startup when the roll diameter of the sheet 2 is large.

  The controller 51 performs printing by the rotation of the printing roller 19 and the sensor roller 7 driven by both the paper motor 8 and the auxiliary motor 9, and then the printing is performed every predetermined time or every predetermined amount of data. It is confirmed whether it has been completed (S25). If printing is completed here (Y in S25), printing ends (S26). If printing has not been completed (N in S15), it is determined again whether the sensor roller 7 is rotating normally (S22).

  In this way, printing is performed by driving the sensor roller 7 by driving both the paper motor 8 and the auxiliary motor 9 until it is recognized that the sensor roller 7 is rotating normally.

  In the middle of printing, the control unit 51 checks whether printing is completed for every predetermined time or printing for a predetermined amount of data (S25), and when printing is not completed (S25) N) again determines whether the sensor roller 7 is rotating normally (S22). If it is determined that the sensor roller 7 is rotating normally (Y in S22), the drive signal to the auxiliary motor 9 is Although transmission is performed, a current lower than the current at which the auxiliary motor 9 rotates at the maximum torque is applied to the auxiliary motor 9 (S27).

  When the roll-shaped paper 2 has a large roll diameter, a large load is applied at the time of starting to move from the stop state, and therefore it is difficult to rotate the sensor roller 7 with only the driving force of the paper motor 8. There is. However, after steady rotation by driving both of the auxiliary motor 9 and the paper motor 8 at the time of starting, the load as much as at the time of starting is not applied, and the sensor roller can be driven even if the auxiliary motor 9 is driven at the maximum torque without assistance. It is possible to maintain a steady rotation of 7.

  While driving the auxiliary motor 9 at a current lower than the current that drives the maximum torque, the control unit 51 performs printing by the rotation of the sensor roller 7 driven by the printing unit 19 and the paper motor 8 (S28). Thereafter, it is confirmed whether or not printing is completed after elapse of a predetermined time or after printing of a predetermined amount of data (S29). If printing is completed (Y in S29), printing ends (S30). If printing has not been completed (N in S29), it is determined again whether the sensor roller 7 is rotating normally (S22).

  As described above, it is determined whether or not the sensor roller 7 is in a steady rotation. If the sensor roller 7 is not in a steady rotation, for example, when the load at start-up is large, the auxiliary motor 9 is driven with the maximum torque and the paper motor 8 is driven. And the sensor roller 7 is driven. When the sensor roller 7 is rotating in a steady state, the auxiliary motor 9 can be driven at the maximum torque so that the paper 2 can be normally conveyed without assistance. By driving the auxiliary motor 9 with a current value lower than the current value for driving the maximum torque, the power consumption of the printer apparatus 1 is reduced.

  In the present embodiment, when the sensor roller 7 does not rotate constantly, the auxiliary motor 9 is supplied with a current that provides the maximum torque. However, the current to be applied does not necessarily need to be applied so that the auxiliary motor 9 has the maximum torque. When the sheet 2 to be used is at the maximum, the driving of the paper motor 8 is assisted and the sensor roller 7 cooperates with the paper motor 8. Any current value can be used as long as the torque can be rotated in a steady manner. Further, the current applied to the auxiliary motor 9 after reaching the steady rotation may be lower than this current.

(Fourth embodiment)
Hereinafter, a printer apparatus 1 according to a fourth embodiment of the present embodiment will be described with reference to FIGS. 10 and 11. In addition, the same code | symbol is attached | subjected in the same component as 2nd Embodiment, and the detailed description is abbreviate | omitted.

  In the fourth embodiment, the steady rotation of the roll-shaped paper 2 is detected, and the necessity of driving the auxiliary motor 9 is not determined based on the result, but the remaining amount of the roll-shaped paper 2 is determined. The current value to be applied to the auxiliary motor 9 is changed based on the detection result.

  Further, only by changing the current value, the driving of the auxiliary motor 9 is not stopped in any result of the detection by the remaining paper amount detection unit. For this reason, the one-way clutch provided between the auxiliary motor 9 and the sensor roller 7 provided in the second embodiment is not provided. Moreover, the detection result of whether the sensor roller 7 is rotating normally is not used. For this reason, the rotation sensor 25 and the through hole 31 which are steady rotation detection parts are not provided.

  The method for detecting the remaining amount of the sheet 2 is the same as that in the second embodiment, and thus detailed description thereof is omitted.

  The driving of the auxiliary motor 9 according to the fourth embodiment will be described with reference to FIG.

  As in the second embodiment, when print data is received from the host computer 50 with the paper 2 set in the printer device 1 (S31), the control unit 51 supplies the paper loaded in the printer device 1. It is determined whether the remaining amount of 2 is large (S32).

  When it is determined that the remaining amount of the paper 2 is large (Y in S32), the roll diameter of the paper 2 is large, and a large load is applied at the time of start-up. The control unit 51 sends a drive signal to the auxiliary motor 9 so that the auxiliary motor 9 is turned on, and rotates the auxiliary motor 9 (S33).

  At this time, the current applied to the auxiliary motor 9 is a current value at which the maximum torque of the auxiliary motor 9 is obtained. Further, when the drive signal is already ON when sending the drive signal to the auxiliary motor 9, the current applied to the auxiliary motor 9 is not changed and the ON state is continued.

  Next, the control unit 51 drives the printing unit 19 to start printing the print data received from the host computer 50 on the first sheet surface 5 of the sheet 2 (S34). In printing, the platen roller 18 is rotated and the thermal print head 17 is driven. At the same time, the paper motor 8 is driven.

  The paper motor 8 is connected to a gear (not shown) of the sensor roller 7 and rotates in the Z direction in FIG. 10, and thus rotates the sensor roller 7 in the X direction. Therefore, a rotational force in the Y direction is applied to the sheet 2 by friction between the sensor roller 7 and the contact roller 30-1.

  That is, both the driving force due to the rotation of the auxiliary motor 9 and the driving force due to the rotation of the paper motor 8 are transmitted to the sensor roller 7. When the remaining amount of the paper 2 is large, the rotation is started from the state where the paper 2 is stopped, and then a large load is required to reach the steady rotation, and it is difficult to rotate the sensor roller 7 with the paper motor 8 alone. is there.

  However, as described above, when the remaining amount of the sheet 2 is large, the auxiliary motor 9 is driven to transmit the driving force to the sensor roller 7. As a result, it is possible to correctly convey the sheet 2 even when a large load is applied at the time of startup when the roll diameter of the sheet 2 is large.

  The controller 51 performs printing by the rotation of the printing roller 19 and the sensor roller 7 driven by both the paper motor 8 and the auxiliary motor 9, and then the printing is performed every predetermined time or every predetermined amount of data. It is confirmed whether it has been completed (S35). If printing is completed (Y in S35), printing ends (S36). If printing has not been completed (N in S35), it is determined whether the remaining amount of the sheet 2 is large (S32).

  In this way, printing is performed by driving the sensor roller 7 by driving both the paper motor 8 and the auxiliary motor 9 until it is recognized that the remaining amount of the sheet 2 is not large.

In the middle of printing, the control unit 51 checks whether printing has been completed for every predetermined time or printing for a predetermined amount of data (S35), and if printing has not ended (S35) N) again determines whether the remaining amount of the sheet 2 is large (S32). If it is determined here that the remaining amount of the sheet 2 is not large (N in S32), the drive signal is transmitted to the auxiliary motor 9. Although this is done, a current lower than the current at which the auxiliary motor 9 rotates at the maximum torque is applied to the auxiliary motor 9 (S37).

  When the roll-shaped paper 2 has a large roll diameter, a large load is applied at the time of starting to move from the stop state, and therefore it is difficult to rotate the sensor roller 7 with only the driving force of the paper motor 8. There is. However, after steady rotation by driving both of the auxiliary motor 9 and the paper motor 8 at the time of starting, the load as much as at the time of starting is not applied, and the sensor roller can be driven even if the auxiliary motor 9 is driven at the maximum torque without assistance. It is possible to maintain a steady rotation of 7.

  While driving the auxiliary motor 9 with a current lower than the current for driving the maximum torque, the control unit 51 performs printing by the rotation of the sensor roller 7 driven by the printing unit 19 and the paper motor 8 (S38). Thereafter, it is confirmed whether or not printing is completed after elapse of a predetermined time or after printing of a predetermined amount of data (S39). If printing is completed here (Y in S39), printing ends (S40). If printing has not been completed (N in S39), it is determined again whether the remaining amount of the sheet 2 is large (S32).

  As described above, it is determined whether the remaining amount of the sheet 2 is large. When the remaining amount of the sheet 2 is large, for example, when the load at the time of starting is large, the auxiliary motor 9 is driven with the maximum torque, and the sensor roller 7 is driven with both the paper motor 8. When the remaining amount of the sheet 2 is small, since the remaining amount of the sheet 2 is small, a current lower than a current value for driving the auxiliary motor 9 with the maximum torque even when the auxiliary motor 9 is driven with the maximum torque even at the start-up. By driving with the value, the sheet 2 can be normally conveyed. By stopping the auxiliary motor 9, the power consumption of the printer apparatus 1 is reduced.

  In the present embodiment, when the remaining amount of the sheet 2 is large, a current at which the auxiliary motor 9 has maximum torque is applied to the auxiliary motor 9. However, the current to be applied does not necessarily need to be applied so that the auxiliary motor 9 has the maximum torque. When the sheet 2 to be used is at the maximum, the driving of the paper motor 8 is assisted and the sensor roller 7 cooperates with the paper motor 8. Any current value can be used as long as the torque can be rotated in a steady manner. Further, the current applied to the auxiliary motor 9 when the remaining amount of the sheet 2 is low should be lower than this current.

  Although several embodiments of the present invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

1: Printer device 2: Paper 7: Sensor roller
8: Paper roller 9: Auxiliary motor 10: One-way clutch 11: Transmission gear 12: Delivery roller 17: Thermal print head 18: Platen roller 20: Cutter

Claims (4)

A paper transport path for pulling out and transporting the wound paper;
A printing unit for printing on the paper;
A roller for rotating the paper in contact with the outer peripheral surface of the paper;
A first motor for applying a driving force to the roller;
A second motor capable of applying an auxiliary driving force to the roller;
A steady rotation detector that detects whether the rotation of the roller is in a steady state;
A printer apparatus comprising: a second motor rotation control unit that decreases a current value applied to the second motor when the steady rotation detection unit detects that the rotation of the roller is in a steady state . The printer apparatus according to claim 1, wherein the steady rotation detection unit detects rotation of the shaft of the roller to detect whether the rotation of the roller is in a steady state. A paper transport path for pulling out and transporting the wound paper;
A printing unit for printing on the paper;
A roller for rotating the paper in contact with the outer peripheral surface of the paper;
A first motor for applying a driving force to the roller;
A second motor capable of applying an auxiliary driving force to the roller;
A remaining paper amount detection unit for detecting the remaining amount of the paper;
And a second motor drive control unit configured to reduce a current value applied to the second motor when the remaining amount of the sheet is detected to be less than a predetermined amount . The paper remaining amount detecting unit includes a light emitting unit that emits light and a light receiving unit that receives light from the light emitting unit, and the light remaining by the light receiving unit receives the light emitted from the light emitting unit. The printer device according to claim 3, wherein the printer device detects that the amount is less than a predetermined amount.

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