JP4603397B2 - Recording device - Google Patents

Description

  The present invention relates to a recording apparatus that records an image using an ink ribbon.

Normally, in a dot impact printer, an operation of transporting an ink ribbon from a ribbon cartridge to a recording head is performed in conjunction with a recording operation by the recording head. May occur (so-called ribbon jam). When a ribbon jam occurs, it is necessary to stop the operation of the dot impact printer promptly in order to prevent damage to each part such as an ink ribbon. For this reason, conventionally, a roller for detecting the conveyance state of the ink ribbon is provided, and control such as stopping the printing operation when the occurrence of ribbon jam is detected is performed (for example, see Patent Document 1).
JP-A-10-35065

  By the way, as a method for quickly dealing with the occurrence of the ribbon jam, there are a method of constantly monitoring the ink ribbon transport state and a method of performing interrupt control when an abnormality occurs in the ink ribbon transport state. However, if the controller that controls the operation of the dot impact printer constantly monitors the state of ink ribbon conveyance, the load increases significantly. Therefore, it is necessary to use an expensive and high-performance processing unit. Moreover, in order to perform interrupt control, it is necessary to allocate an interrupt resource, which is inefficient.

  The present invention has been made in view of the above-described circumstances. In a recording apparatus that records an image by ejecting a recording wire from an ink ribbon via an ink ribbon, the load of a control unit that controls the operation of the recording apparatus is reduced. It is an object of the present invention to be able to quickly cope with the occurrence of an ink ribbon abnormality without increasing it.

  In order to solve the above-described problems, the present invention includes a plurality of driving units that drive the respective units, and the plurality of driving units are controlled by a control unit so that a carriage on which a recording head is mounted is scanned on a recording medium. At the same time, in a recording apparatus that ejects a recording wire from the recording head and records an image on the recording medium via an ink ribbon, a winding mechanism for winding the ink ribbon and an abnormality in the operating state of the winding mechanism are detected. And a stop control means for stopping power supply to each of the drive units, and writing the value indicating the winding abnormality to the register, the control means refers to the value of the register, and the value is wound. In the case where the value is a value indicating an error in taking out, a return process is performed in order to return the power supply to the drive unit.

  According to the present invention, the stop control means detects an abnormality in the operation state of the winding mechanism that winds up the ink ribbon, writes a value indicating the winding abnormality in the register, and supplies power to the drive unit of the recording apparatus. The supply is stopped, and the control means refers to the value of the register. When the value indicates a winding abnormality, the recovery process is performed to restore the power supply to the drive unit. When an abnormality occurs, the operation of the drive unit stops without being controlled by the control means. As a result, when an abnormality in the winding state of the ink ribbon occurs, the operation of the drive unit is quickly stopped according to the control by the stop control means, so that the abnormal winding of the ink ribbon can be handled very quickly. It becomes possible. In this case, it is not necessary for the control means for controlling each part of the printing apparatus to constantly monitor the winding state of the ink ribbon, and it is not necessary to perform interrupt processing for the control means, so that it is not necessary to increase the load on the control means. There are advantages. In addition, when the supply of power to the drive unit is stopped due to an abnormal winding of the ink ribbon, the power supply to the drive unit is restored according to the control by the control means. After the trouble related to the ink ribbon is solved by the work, the normal operation can be resumed promptly. Furthermore, since the power supply to the drive unit does not return unless the register value indicates a winding abnormality, the power supply should not be restored, for example, when a serious failure occurs in a part other than the ink ribbon. Can also be dealt with appropriately.

  In the present invention, the control means may refer to the value of the register every predetermined time.

  In this case, the control unit refers to the value of the register every predetermined time, and when the register value is a value indicating a winding abnormality, the power supply to the drive unit is restored. There is an advantage that the load on the control means can be extremely low compared with the case of constantly monitoring abnormalities or performing interrupt processing.

  Further, in the present invention, after the control unit returns the power supply to the drive unit in the return process, the control unit further operates at least a part of the drive unit to change the state of the recording apparatus. The ink ribbon may be shifted to a predetermined state suitable for an operation for eliminating the abnormality in the winding state of the ink ribbon.

  In this case, after the power supply to the drive unit is restored by the return process of the control means, at least a part of the drive unit is further operated to be in a predetermined state suitable for the work for eliminating the abnormality in the winding state of the ink ribbon. Since it shifts, it becomes easy to perform various operations for eliminating the abnormality, and normal operation can be resumed promptly.

  In the present invention, the driving unit includes at least a carriage driving unit that scans the carriage, and a gap adjustment unit that adjusts a gap between the recording head and the recording medium, and the control unit includes: When the recording apparatus is shifted to the predetermined state, the carriage driving unit may be operated to move the carriage to a predetermined retracted position, and the gap adjusting unit may be operated to expand the gap.

  In this case, the drive unit includes at least a carriage drive unit that scans the carriage, and a gap adjustment unit that adjusts the gap between the recording head and the recording medium. The drive unit operates to move the carriage to a predetermined retracted position, and the gap adjusting unit operates to enlarge the gap between the recording head and the recording medium. Therefore, an abnormality has occurred in the winding state of the ink ribbon. In this case, the operation of each part of the recording apparatus is stopped, and each part is in an optimum state for work such as removal and replacement of the ink ribbon. Accordingly, the work for eliminating the problems associated with the ink ribbon is facilitated, so that the normal operation can be resumed promptly.

  According to the present invention, the stop control means detects an abnormality in the operation state of the take-up mechanism that winds up the ink ribbon, stops the power supply to the drive unit of the recording apparatus, and the control means sets the register value. Since the power supply to the drive unit is restored based on this, when an abnormality occurs in the winding state of the ink ribbon, the operation of the drive unit can be stopped without being controlled by the control unit. It is possible to cope with an abnormal winding of the ink ribbon very quickly without increasing the load.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an external perspective view of a dot impact printer 10 according to an embodiment of the present invention, and FIG. 2 is a rear view of the dot impact printer 10. 3 is a perspective view showing the configuration of the recording mechanism unit 20 incorporated in the dot impact printer 10, and FIG. 4 is a cross-sectional view of the recording mechanism unit 20 taken along the line AA 'in FIG. Note that the illustration of the recording head 30 is omitted in FIG. FIG. 5 is a top view of the dot impact printer 10 with the top cover 13 opened, and FIG. 6 is a top view of the dot impact printer 10 with the top cover 13 opened and the ribbon cartridge 50 attached. .
A dot impact printer 10 as a recording apparatus of the present invention records an image including characters by ejecting a recording wire via an ink ribbon onto a recording surface of a recording medium by a recording head 30 that ejects a plurality of recording wires. To do. Here, as the recording medium, various forms of sheets (including paper and resin sheets) such as cut paper, continuous paper, and copying paper can be used. In the present embodiment, the above recording medium is used. An example using continuous paper will be described.

As shown in FIG. 1, the dot impact printer 10 has a substantially box-shaped exterior made up of an upper case 11 and a lower case 12, and a recording mechanism section 20 (FIG. 3) is built in the exterior.
An upper surface cover 13 is disposed on the front surface of the upper case 11 and is opened upward when a ribbon cartridge 50 (FIG. 6) described later is mounted on the recording mechanism unit 20. A front paper feed port 111 for supplying continuous paper to the recording mechanism unit 20 is opened at the lower front surface of the upper case 11. A front cover 15 that opens forward is disposed above the front paper feed port 111 so that continuous paper can be set in the recording mechanism unit 20 by opening the front cover 15.
As shown in FIGS. 1 and 2, the upper case 11 is provided with an upper back cover 14 that is continuous from the rear upper surface of the upper case 11 to the rear surface. The upper back cover 14 is opened toward the rear of the upper case 11 during maintenance of the recording mechanism unit 20 described later. A paper discharge port 113 through which the continuous paper after recording is discharged is opened on the back surface of the upper back cover 14.
Further, on the back surface of the upper case 11, a rear paper feed port 112 for supplying continuous paper to the recording mechanism unit 20 is opened below the upper back cover 14.
Further, as shown in FIG. 2, an I / F cover 16 is disposed at the lower back of the lower case 12. A connector (not shown) for connecting the dot impact printer 10 to various devices such as a computer is disposed inside the I / F cover 16. The I / F cover 16 is opened and a cable is connected to the connector. Can be connected.
As shown in FIG. 1, an operation panel 121 is disposed on the upper front surface of the upper case 11. The operation panel 121 includes switches for performing various settings related to the operation of the dot impact printer 10, an indicator for notifying the operation state, a liquid crystal display panel, and the like. At the front corner of the lower case 12, a switch 122 for turning on / off the power source of the dot impact printer 10 is disposed. As shown in FIG. 2, a power connector 123 is disposed on the back surface of the lower case 12. The power connector 123 is connected to a power supply circuit 71 (FIG. 15) that supplies power to each unit of the dot impact printer 10.

  Next, the configuration of the recording mechanism unit 20 will be described. As shown in FIGS. 3 and 4, the recording mechanism unit 20 includes a right side frame 21, a left side frame 22, a front frame 23, and a base frame 24 as main body frames. The main body frame is provided with a recording head 30, a carriage 28 for mounting the recording head 30, a front paper feed mechanism 26 that supplies continuous paper to the recording head 30 from the front side, and a recording paper 30 from the rear side. A rear paper feeding mechanism 27 that supplies continuous paper, a transport mechanism 34 that conveys the continuous paper supplied by the front paper feeding mechanism 26 and the rear paper feeding mechanism 27 toward the recording head 30, and recording by the recording head 30. A paper discharge mechanism 35 for discharging the continuous paper and a ribbon drive unit 37 for driving the ribbon cartridge 50 (FIG. 6) are disposed.

The right side frame 21 and the left side frame 22 are erected so as to face each other at both ends of the recording mechanism unit 20, and the front frame 23 and the base frame 24 are interposed between the right side frame 21 and the left side frame 22. It is bridged. The front frame 23 is located on the front side of the recording mechanism unit 20, and the base frame 24 is located on the rear side below the recording mechanism unit 20.
Rollers 25 are respectively provided at lower front portions of the right side frame 21 and the left side frame 22, and the recording mechanism unit 20 is supported by the lower case 12 via these two rollers 25. Further, the roller 25 is configured to be rotatable, and the control mechanism (not shown) disposed below the recording mechanism unit 20 can be maintained by tilting the recording mechanism unit 20 toward the front side with the roller 25 as a fulcrum. .
The front paper feed mechanism 26 includes a front paper feed table 261 disposed in the lower front portion of the recording mechanism unit 20, a tractor support shaft 263, which extends in parallel between the right side frame 21 and the left side frame 22, and A tractor drive shaft 264, a pair of left and right front tractors 262, and a front tractor cover 266 attached integrally to each front tractor 262 are provided.
The front paper feed tray 261 has a surface extending obliquely upward from substantially the lower end of the front surface of the recording mechanism unit 20, and supports continuous paper inserted from the front paper feed port 111 (FIG. 1) from below. To do. A tractor support shaft 263 and a tractor drive shaft 264 are disposed above the front sheet feed table 261, and a pair of left and right front tractors 262 are inserted through the tractor support shaft 263 and the tractor drive shaft 264. Each of the front tractors 262 has a flat surface portion, and the flat surface portion is arranged so as to be continuous with the surface of the front paper feed table 261. The front tractor 262 includes a tractor belt (not shown) having a plurality of pins 265. The tractor belt is hung on the tractor support shaft 263 and the tractor drive shaft 264. The tractor support shaft 263 is rotatably arranged, while the tractor drive shaft 264 is driven and rotated by the transport motor 73 (FIG. 15). The tractor belt rotates with the rotation of the tractor drive shaft 264 and moves the pin 265 along the plane of the front tractor 262. The pin 265 is exposed from the flat surface portion of the front tractor 262, and engages with sprocket holes formed at both ends of the continuous paper. When the tractor belt rotates and the pin 265 moves, the continuous paper is conveyed to the recording head 30 side.
The front tractor 262 is provided with a front tractor cover 266 that covers the pin 265 from above. By placing the continuous paper on the front tractor 262 and covering the front tractor cover 266, the state where the pin 265 is engaged with the sprocket hole of the continuous paper is maintained.

The rear paper feed mechanism 27 includes a tractor support shaft 272 and a tractor drive shaft 273 that are spanned in parallel between the right side frame 21 and the left side frame 22, a pair of left and right rear tractors 271, and each rear tractor 271. A rear tractor cover 275 attached integrally and a sprocket wheel 276 disposed behind the rear tractor 271 are provided.
On the rear side of the recording mechanism unit 20, a part of the base frame 24 is formed in a plane at a position corresponding to the rear sheet feed port 112 (FIG. 2), and is inserted from the rear sheet feed port 112 by this plane. The continuous paper is supported from below. A tractor support shaft 272 and a tractor drive shaft 273 are arranged side by side on the base frame 24, and two rear tractors 271 are inserted through the tractor support shaft 272 and the tractor drive shaft 273. The rear tractor 271 has a flat portion, and the flat portion is disposed so as to be continuous with the flat surface formed by the base frame 24.
The rear tractor 271 includes a tractor belt (not shown) having a plurality of pins 274, and this tractor belt is spanned between a tractor support shaft 272 and a tractor drive shaft 273, and is conveyed by a transport motor 73 (FIG. 15). The tractor drive shaft 273 is driven to rotate. The pin 274 is exposed on the flat surface portion of the rear tractor 271 and engages with a sprocket hole formed in the continuous paper. Then, the pin 274 is moved by the rotation of the tractor belt, and the continuous paper is conveyed to the front side.
A sprocket wheel 276 is disposed behind the rear tractor 271. The sprocket wheel 276 is a pair of left and right ring-shaped members inserted through a shaft spanned between the right side frame 21 and the left side frame 22, and the shaft is driven by the transport motor 73 (FIG. 15). Rotate with. A plurality of pins 277 are arranged on the circumferential surface of the sprocket wheel 276, and these pins 277 are engaged with the sprocket holes of the continuous paper conveyed from the rear tractor 271 from above. Then, the continuous paper is wound up by the rotation of the sprocket wheel 276 and conveyed toward the recording head 30.
The rear tractor 271 is provided with a rear tractor cover 275 that covers the pin 277 from above. By placing the continuous paper on the rear tractor 271 and covering the rear tractor cover 275, the state in which the pins 274 are engaged with the sprocket holes of the continuous paper is maintained.

The transport mechanism 34 includes a first transport roller 341 that contacts the back surface of the continuous paper, a second transport roller 342 that faces the first transport roller 341 via the continuous paper, and a second transport that pivotally supports the second transport roller 342. A conveyance roller shaft 343 and a platen 31 disposed to face the recording head 30 are provided.
The first conveying roller 341 is disposed above the sprocket wheel 276 and abuts against the back surface of the continuous paper. A second transport roller shaft 343 is disposed at a position facing the first transport roller 341 across the continuous sheet. The second transport roller shaft 343 is rotatably spanned between the right side frame 21 and the left side frame 22, and a plurality of second transport rollers 342 are inserted therethrough. The second conveying roller shaft 343 can be moved within a predetermined range by the operation of the roller opening / closing motor 72 (FIG. 15), and when the roller opening / closing motor 72 opens, the second conveying roller 342 becomes the first conveying roller. When the roller opening / closing motor 72 is separated from the 341 and performs a closing operation, the second conveyance roller 342 is urged toward the first conveyance roller 341.
When the roller opening / closing motor 72 performs a closing operation, the continuous paper is sandwiched and supported between the first transport roller 341 and the second transport roller 342. The first transport roller 341 is driven by the transport motor 73 (FIG. 15) and the drive wheel train 33, and is sandwiched between the first transport roller 341 and the second transport roller 342 as the first transport roller 341 rotates. The continuous paper is conveyed upward, that is, toward the recording head 30 side.

The carriage 28 is inserted through a carriage shaft 29 spanned between the right side frame 21 and the left side frame 22. A belt is mounted on the carriage 28 between a carriage drive motor 32 and a carriage drive pulley (not shown). The belt is driven by the carriage drive motor 32 and the carriage drive pulley, and thus along the carriage shaft 29. Moving.
A recording head 30 is mounted on the carriage 28. The recording head 30 faces the recording surface of continuous paper above the transport mechanism 34, and an ink ribbon 51 (FIG. 6) described later is disposed between the recording surface of the continuous paper and the recording head 30. By ejecting a recording wire (not shown) from the recording head 30 toward the continuous paper, ink adheres to the recording surface of the continuous paper, and an image including characters is recorded.
At a position facing the recording head 30, a platen 31 is disposed on the back side of the continuous paper. The platen 31 is a flat platen having a plane in contact with the continuous paper, and supports the protruding output of the recording wire in this plane. The platen 31 is configured to be movable in a direction perpendicular to the continuous paper, and is urged toward the continuous paper by a spring (not shown).
The carriage 28 is equipped with a gap adjustment motor 75 (FIG. 15). By the operation of the gap adjusting motor 75, the gap between the recording head 30 and the continuous paper and the platen 31 is adjusted as appropriate.

The paper discharge mechanism 35 includes a first paper discharge roller 351 that contacts the continuous paper recorded by the recording head 30 from the back side, a movable frame 353 disposed from the right side frame 21 to the left side frame 22, and a movable frame 353. , A movable shaft 354 and a unit support shaft 355, a spring 356 assembled across the movable frame 353 and the left side frame 22, a plurality of paper discharge roller units 357 fixed to the movable frame 353, and a paper discharge roller And a second paper discharge roller 358 assembled in the unit 357.
The first paper discharge roller 351 is in contact with the back surface of the continuous paper above the recording head 30 and is driven to rotate by the transport motor 73 (FIG. 15) and the drive wheel train 33. A movable shaft 354 and a unit support shaft 355 are disposed at a position facing the first paper discharge roller 351 via the continuous paper. The movable shaft 354 and the unit support shaft 355 are spanned between the right side frame 21 and the left side frame 22, and the unit support shaft 355 is fixed to the right side frame 21 and the left side frame 22, while the movable shaft 354. Is movable so as to draw a circle around the unit support shaft 355. The movable frame 353 is fixed to the movable shaft 354 and the unit support shaft 355 and is movable together with the movable shaft 354.
A plurality of paper discharge roller units 357 arranged in the axial direction of the movable shaft 354 and the unit support shaft 355 are attached to the movable frame 353. A second paper discharge roller 358 is assembled to each of the paper discharge roller units 357 at positions separated from the unit support shaft 355.
The movable frame 353 is urged in a direction approaching the first paper discharge roller 351 about the unit support shaft 355 by a spring 356 spanned between the left side frame 22. Therefore, the second paper discharge roller 358 included in the paper discharge roller unit 357 is urged in a direction to be pressed against the first paper discharge roller 351, and the continuous paper is fed to the first paper discharge roller 351 and the second paper by this urging force. It is sandwiched between the paper discharge rollers 358.
Further, the movable shaft 354 is moved against the urging force of the spring 356 by the operation of the roller opening / closing motor 72 (FIG. 15). That is, when the roller opening / closing motor 72 opens, the movable shaft 354 moves against the urging force of the spring 356 by the driving force of the roller opening / closing motor 72, and the second paper discharge roller 358 is moved to the first paper discharge roller. Separate from 351. When the roller opening / closing motor 72 releases the driving force (closing operation), the second paper discharge roller 358 is pressed against the first paper discharge roller 351 by the biasing force of the spring 356.

As shown in FIG. 5, a ribbon drive unit 37 as a winding mechanism of the present invention is disposed at the right end on the front side of the recording mechanism section 20. The ribbon drive unit 37 is fixed to the right side frame 21 as shown in FIG. 3, and includes a substantially box-shaped cover, a ribbon take-up shaft 38 and a take-up detection shaft 40 protruding from the cover.
Further, as shown in FIG. 5, a ribbon cartridge support claw 36 is disposed at the left end portion on the front side of the recording mechanism unit 20. The ribbon cartridge support claw 36 is a plate-like member formed integrally with the left side frame 22.
As shown in FIG. 6, the ribbon cartridge 50 is mounted on the recording mechanism unit 20 across the ribbon cartridge support claw 36 and the ribbon drive unit 37. In the mounted state shown in FIG. 6, the ribbon cartridge 50 is positioned above the carriage 28, and the ink ribbon 51 extending from the ribbon cartridge 50 passes between the recording head 30 and the continuous paper.
Hereinafter, the configurations of the ribbon drive unit 37 and the ribbon cartridge 50 will be described in detail.

7 is a perspective view showing configurations of the right side frame 21 and the ribbon drive unit 37, and FIG. 8 is a perspective view showing a state in which the cover of the ribbon drive unit 37 is removed. FIG. 9 is a cross-sectional view of the ribbon drive unit 37.
As shown in FIG. 7, the ribbon take-up shaft 38 and the take-up detection shaft 40 protrude from the cover of the ribbon drive unit 37. As shown in FIGS. 8 and 9, in the cover of the ribbon drive unit 37, a gear 382 is formed at the root of the ribbon take-up shaft 38, and the gear 382 meshes with the drive shaft 39. The drive shaft 39 is driven to rotate by the ribbon drive motor 74 (FIG. 15), and the ribbon take-up shaft 38 rotates as the drive shaft 39 rotates.
In addition, a rotor 402 having a plurality of radially extending blades is disposed at the base of the winding detection shaft 40. The rotor 402 is assembled with the winding detection shaft 40 so as to be rotatable. Further, a take-up sensor 41 is disposed in the vicinity of the take-up detection shaft 40 so as to overlap the blades of the rotor 402 from above. The winding sensor 41 is a sensor that detects the presence of the blades of the rotor 402 below the winding sensor 41. The winding sensor 41 performs a detection operation according to a predetermined cycle. When the blade is detected during the detection operation, a high level signal is output. If not detected, a low level signal is output.

When the winding detection shaft 40 rotates, the rotor 402 disposed at the base of the winding detection shaft 40 rotates, and the blades of the rotor 402 sequentially pass under the winding sensor 41. The winding sensor 41 switches the signal level of the output signal every time the blades of the rotor 402 pass. In other words, the winding sensor 41 functions as a rotary encoder by detecting the blades of the rotor 402 and outputs a pulse signal corresponding to the rotation of the rotor 402. Based on the change in the output signal of the winding sensor 41, the rotation angle of the rotor 402, that is, the rotation angle of the winding detection shaft 40 can be detected.
Further, a tooth portion 381 is formed at the tip of the ribbon take-up shaft 38. The tooth portion 381 includes a plurality of teeth extending radially in the radial direction of the ribbon take-up shaft 38, and is engaged with a groove 57 (FIG. 13) formed in the take-up roller 56 (FIG. 13) when the ribbon cartridge 50 is mounted. Match. For this reason, the winding roller 56 rotates when the ribbon winding shaft 38 rotates. Similarly, a tooth portion 401 having a plurality of teeth extending in the radial direction of the take-up detection shaft 40 is formed at the tip of the take-up detection shaft 40, and this tooth portion 401 is formed on the driven roller 58 (FIG. 13). Engage with the formed groove 59. For this reason, when the driven roller 58 rotates, the winding detection shaft 40 rotates together with the driven roller 58.

FIG. 10 is an external perspective view showing the configuration of the ribbon cartridge 50, and FIG. 11 is a top view of the ribbon cartridge 50. FIG. 12 is a cross-sectional view of the ribbon cartridge 50.
As shown in each of FIGS. 10 to 12, the ribbon cartridge 50 has a flat case 53. The case 53 is formed with a ribbon storage portion 55 for storing the ink ribbon 51, and the ink ribbon 51 formed in an endless shape is folded and stored. The ink ribbon 51 is taken up in the case 53 by the take-up roller 56 and the driven roller 58, and is sent out of the case 53 through the ribbon storage portion 55 and circulates.
The winding protrusion 54 protruding from the case 53 communicates with the winding roller 56 in the case 53. By rotating the winding protrusion 54 by hand, the winding roller 56 is rotated to wind the ink ribbon 51. Can do.
The ink ribbon 51 is inserted through the ribbon guide 52 outside the case 53. The ribbon guide 52 is mounted on the carriage 28 (FIG. 5) and supports the ink ribbon 51 so that the ink ribbon 51 passes between the recording head 30 and the continuous paper. 10 to 12 show a state in which the ribbon guide 52 is locked to the side surface of the case 53. However, when the ribbon cartridge 50 is used, the ribbon guide 52 is detached from the case 53 and the carriage 28 is moved. It is attached to.

FIG. 13 is an enlarged view of a main part of the cross-sectional view shown in FIG. FIG. 14 is a longitudinal sectional view of the ribbon cartridge 50 and shows a section taken along line BB ′ of FIG. As shown in FIGS. 13 and 14, a groove 57 is formed at the axial center of the take-up roller 56. As described above, the groove 57 is formed at the tip of the ribbon take-up shaft 38 (FIG. 9). The tooth portion 381 thus engaged is engaged. The driven roller 58 faces the take-up roller 56 with the ink ribbon 51 interposed therebetween. The driven roller 58 is biased toward the take-up roller 56 by a spring (not shown) or the like, and sandwiches the ink ribbon 51 together with the take-up roller 56. A groove 59 is formed at the shaft center of the driven roller 58. As described above, the tooth portion 401 formed at the tip of the winding detection shaft 40 (FIG. 9) is engaged with the groove 59. Match.
Therefore, in a state where the ribbon cartridge 50 is mounted on the recording mechanism unit 20, the take-up roller 56 is rotated by the rotation of the ribbon take-up shaft 38 of the ribbon drive unit 37 (FIG. 9), and the ink ribbon 51 is placed in the case 53. Rolled up. When the driven roller 58 rotates with the rotation of the winding roller 56, the winding detection shaft 40 rotates with the driven roller 58, and the signal level of the output signal of the winding sensor 41 changes.

FIG. 15 is a functional block diagram of the control unit 60 that controls the operation of the dot impact printer 10. The control unit 60 shown in FIG. 15 is mounted on a control board (not shown) included in the dot impact printer 10.
The control unit 60 includes a controller 61, an interface 65, a power supply control unit 66, a recording head drive unit 67, a motor driver 68, and a ribbon take-up detection unit 69 as a stop control unit of the present invention. Are connected by a bus 60a.
The controller 61 includes a CPU (Central Processing Unit) 62, a ROM (Read Only Memory) 63, and a RAM (Random Access Memory) 64 as control means of the present invention, and reads a control program stored in the ROM 63. The data is expanded on the RAM 64 and executed by the CPU 62. The controller 61 controls the operation of the dot impact printer 10 by driving and controlling each function unit of the control unit 60.
The interface 65 is connected to an external device (computer or the like) via a communication cable, and transmits / receives various data to / from the external device under the control of the controller 61.
A power supply circuit 71 is connected to the power controller 66. The power supply circuit 71 converts the AC power supplied from the power connector 123 (FIG. 2) into a DC voltage having a predetermined voltage value, and supplies power to each unit of the dot impact printer 10. The power supply is turned ON / OFF according to the input control signal. The power control unit 66 outputs a control signal to the power supply circuit 71 to turn on / off power supply from the power supply circuit 71 to each unit of the dot impact printer 10.
The recording head drive unit 67 is connected to the recording head 30 and controls the recording wire protruding operation by the recording head 30.
The motor driver 68 is connected to each of a carriage drive motor 32 as a carriage drive unit, a roller opening / closing motor 72, a transport motor 73, a ribbon drive motor 74, and a gap adjustment motor 75 as a gap adjustment unit. The motor driver 68 supplies power to each of these motors based on the driver driving power supply P supplied from the power supply circuit 71. Here, the transport motor 73 and the ribbon drive motor 74 are stepping motors. The motor driver 68 controls the operation of the stepping motor by turning on / off the power supply or outputting a pulse, and for other motors, switching the power supply on / off. The operation is controlled by applying a reverse voltage.
The ribbon take-up detection unit 69 acquires the output signal of the take-up sensor 41 included in the ribbon drive unit 37 (FIG. 8) and outputs it to the controller 61.

  The controller 61 controls the interface 65 during the recording operation of the recording mechanism unit 20 to acquire various data such as print data, controls the motor driver 68 based on the acquired data, and the carriage driven by the carriage drive motor 32. 28 (FIG. 3), opening / closing operation of each roller by the roller opening / closing motor 72, continuous paper conveying operation by the conveying motor 73, winding operation of the ink ribbon 51 (FIG. 6) by the ribbon driving motor 74, by the gap adjusting motor 75. A gap adjusting operation or the like is executed, and the recording head driving unit 67 is controlled to cause the recording wire to protrude from the recording head 30.

In the dot impact printer 10 configured as described above, when the ribbon cartridge 50 (FIG. 6) is attached, the operation of the ribbon drive motor 74 (FIG. 15) for one step is performed by the ribbon drive unit 37 (FIG. 8). ) Of the rotor 402 corresponding to the rotation of one blade. Hereinafter, this point will be described in detail.
When a pulse is input to the ribbon drive motor 74, the ribbon drive motor 74 rotates by a predetermined angle, and this rotation is transmitted through the drive shaft 39 and the ribbon take-up shaft 38, and the take-up roller 56 of the ribbon cartridge 50 is moved. Rotate. Here, the rotation of the take-up roller 56 is transmitted to the driven roller 58 facing the take-up roller 56 via the ink ribbon 51. When the driven roller 58 rotates, the winding detection shaft 40 engaged with the driven roller 58 rotates, and thereby the rotor 402 rotates. The rotor 402 has a configuration in which the plurality of blades described above are arranged uniformly, and the width of each blade and the width between the blades are substantially the same at a position overlapping the lower side of the winding sensor 41. It has become.
Here, the operation angle of one pulse of the ribbon drive motor 74 is such that the rotor 402 rotates by one blade below the winding sensor 41, and the presence / absence of the blade of the rotor 402 is switched. It is set to an angle. This configuration includes a rotation ratio between the ribbon drive motor 74 and the drive shaft 39, a rotation ratio between the drive shaft 39 and the ribbon take-up shaft 38, and a rotation ratio (diameter ratio) between the ribbon take-up shaft 38 and the take-up roller 56. The rotation ratio (diameter ratio) between the winding roller 56 and the driven roller 58, the rotation ratio (diameter ratio) between the driven roller 58 and the winding detection shaft 40, and the rotor with respect to the diameter of the winding detection shaft 40 This can be realized by appropriately adjusting the size of the blades 402.
With this configuration, every time the ribbon drive motor 74 rotates by one step, the output signal of the winding sensor 41 switches from the High level to the Low level or from the Low level to the High level. That is, when the output signal of the winding sensor 41 is viewed as a pulse signal, the pulse width of this pulse signal corresponds to one step of the ribbon drive motor 74.
The ribbon drive motor 74 is configured as a stepping motor for 1-2 phase excitation. Each time a pulse is input to the ribbon drive motor 74, the ribbon drive motor 74 alternately switches between 1-phase excitation and 2-phase excitation. Change. In this case, the phase switching in the ribbon drive motor 74 and the output level switching of the output signal in the winding sensor 41 are synchronized. Therefore, for example, when the ribbon drive motor 74 is switched from 1 phase to 2 phases, the output signal of the winding sensor 41 is switched from High level to Low level, and when the ribbon drive motor 74 is switched from 2 phases to 1 phase. A correspondence relationship is established in which the output signal of the winding sensor 41 is switched from the low level to the high level.

When the dot impact printer 10 performs a recording operation, the ink ribbon 51 of the ribbon cartridge 50 is wound by the operation of the ribbon drive unit 37 as described above in accordance with the recording head 30 protruding the recording wire. Taken. Due to the winding operation of the ink ribbon 51, new portions of the ink ribbon 51 are successively supplied between the recording head 30 and the continuous paper so that a clear image can be recorded.
However, when the ink ribbon 51 is twisted, caught, etc., the ink ribbon 51 cannot be smoothly wound, and so-called ribbon jam occurs. When the ribbon jam occurs, not only the recording quality deteriorates, but also the continuous operation, the carriage 28, the recording head 30, etc. may be damaged or damaged, and the ink ribbon 51 may be damaged. Work to eliminate the ribbon jam.
Therefore, the dot impact printer 10 according to the present embodiment executes the ribbon jam detection process (FIG. 16) by the ribbon winding detection unit 69 included in the control unit 60 during the execution of the recording operation, and when a ribbon jam occurs. In order to prevent damage to each part including the ink ribbon 51, the operation of the dot impact printer 10 is stopped. Further, after executing the ribbon jam detection process by the ribbon take-up detection unit 69, the CPU 62 executes a ribbon jam handling process (FIG. 17) so that the operator can quickly remove the ribbon jam.

FIG. 16 is a flowchart showing a ribbon jam detection process executed by the ribbon take-up detection unit 69. The ribbon jam detection process shown in FIG. 16 is executed while the ribbon ribbon motor 74 is winding the ink ribbon 51.
In the ribbon jam detection process, the ribbon take-up detection unit 69 obtains an output signal output from the take-up sensor 41 and a drive signal output from the motor driver 68 to the ribbon drive motor 74 (step S11). In this step S11, the output signal of the winding sensor 41 and the drive signal of the ribbon drive motor 74 for a predetermined time are acquired. Subsequently, the CPU 62 counts the number of operation steps of the ribbon drive motor 74 corresponding to the pulse of the output signal of the winding sensor 41 (step S12). Further, the ribbon take-up detection unit 69 acquires an upper limit value and a lower limit value for error determination from an error determination upper limit value register (not shown) and an error determination lower limit value register (not shown), respectively (step S13). The ribbon take-up detection unit 69 compares the count value counted in step S12 with the upper limit value and the lower limit value acquired in step S13, and determines whether or not the count value is between the upper limit value and the lower limit value. That is, it is determined whether or not the condition shown in the following formula (1) is satisfied (step S14).
Lower limit value ≤ count value ≤ upper limit value (1)

  As described above, the output signal of the winding sensor 41 is a pulse signal that switches between the high level and the low level each time the blades of the rotor 402 (FIG. 8) pass below the winding sensor 41. One minute corresponds to one step of the ribbon drive motor 74. That is, the number of pulses of the winding sensor 41 and the number of operation steps of the ribbon drive motor 74 have a correlation. However, when a ribbon jam occurs, the rotor 402 does not rotate regardless of the rotation of the ribbon drive motor 74, so that the number of pulses of the winding sensor 41 is significantly different from the number of operation steps of the ribbon drive motor 74. Become. Therefore, for the output signal of the winding sensor 41 for a predetermined time, the pulse is converted into the number of operation steps of the ribbon drive motor 74, and the converted value and the number of operation steps of the ribbon drive motor 74 for the predetermined time are obtained. By comparison, it can be determined whether or not the rotor 402 has rotated normally, that is, whether or not a ribbon jam has occurred. Accordingly, in step S14, the ribbon take-up detection unit 69 stores in advance an error determination upper limit value register (not shown) and an error determination lower limit value register (not shown) according to the number of operation steps of the ribbon drive motor 74 for a predetermined time. By comparing the stored upper limit value and lower limit value with the count value in step S12, it is determined whether or not ribbon jam has occurred.

Here, when the count value is within the upper limit value and the lower limit value (step S14; Yes), the ribbon winding detection unit 69 returns to step S11. If the count value is larger than the upper limit value or smaller than the lower limit value (step S14; No), the ribbon winding detection unit 69 increments the count value of an error number counter (not shown) that counts the number of errors (+1). (Step S15). Next, the ribbon take-up detection unit 69 acquires the number of errors set in advance as a criterion for error determination (step S16). Then, the ribbon take-up detection unit 69 compares the acquired error count with the count value of the error count counter, and determines whether or not the count value of the error count counter has reached the error count (step S17).
If the count value of the error number counter has not reached the number of errors (step S17; No), the ribbon winding detection unit 69 returns to step S11. If the count value of the error counter reaches the number of errors (step S17; Yes), the ribbon take-up detection unit 69 determines that a ribbon jam has occurred, and displays a ribbon in an alarm factor register (not shown). The jam occurrence flag is set to 1 (step S18), and the ribbon take-up detection unit 69 outputs a signal indicating that the driver drive power source P is turned off to the power control unit 66, and the power control unit 66. Outputs a control signal to the power supply circuit 71 to turn off the driver drive power supply P based on the signal from the ribbon take-up detection unit 69 (step S19).
In accordance with the control signal output from the power supply controller 66 in step S19, the power supply circuit 71 switches the output of the driver drive power supply P to the motor driver 68 to OFF. As a result, in the dot impact printer 10, the operations of the carriage drive motor 32, roller opening / closing motor 72, transport motor 73, ribbon drive motor 74, and gap adjustment motor 75 are all stopped.

  In the ribbon jam detection process shown in FIG. 16, the winding operation of the ink ribbon 51 is constantly monitored based on the output signal of the winding sensor 41, and if an abnormality occurs in the winding operation, the motor driver 68 is detected. The supply of the driver driving power P is quickly stopped. For this reason, when an abnormality occurs in the ink ribbon 51, each motor driven by the motor driver 68 is promptly stopped according to the control of the ribbon take-up detection unit 69. Can be prevented. The operation of detecting the abnormality of the winding state of the ink ribbon 51 and stopping the supply of the driver driving power P is performed without the CPU 62 of the controller 61 being interposed. That is, it is not necessary to constantly monitor the operation of the winding sensor 41 by the processing of the CPU 62 or to perform interrupt processing for the CPU 62. For this reason, it is possible to quickly cope with an abnormality in the winding state of the ink ribbon 51 without increasing the load on the CPU 62.

FIG. 17 is a flowchart showing a ribbon jam handling process executed by the CPU 62. The CPU 62 executes this ribbon jam handling process every predetermined time.
In the ribbon jam handling process, the CPU 62 detects a flag of an alarm factor register (not shown) (step S21), and determines whether or not the ribbon jam occurrence factor flag is set to 1 (step S22).
If the ribbon jam occurrence factor flag is not set to 1 (step S22; No), the CPU 62 returns to step S21.
If the ribbon jam occurrence factor flag is set to 1 (step S22; Yes), the ribbon jam is detected by the ribbon jam detection process (FIG. 16), and the supply of the driver driving power P to the motor driver 68 is stopped. ing. Accordingly, the CPU 62 controls the power supply control unit 66 to output a control signal to the power supply circuit 71 so as to turn on the supply of the driver drive power supply P (step S23). As a result, the supply of the driver driving power P to the motor driver 68 from the power supply circuit 71 is resumed. The motor driver 68 causes the carriage driving motor 32, the roller opening / closing motor 72, the conveying motor 73, the ribbon driving motor 74, and the gap adjusting motor to 75 motors can be operated. However, these motors are in a standby state for the control of the motor driver 68, and are stopped here.

Next, the CPU 62 performs an operation for notifying the occurrence of ribbon jam. Examples of the notification operation include an operation of displaying a message (such as “RF JAM ALARM”) for guiding the occurrence of a ribbon jam on the liquid crystal display panel included in the operation panel 121 (FIG. 1), and an operation of blinking the indicator. .
Further, the CPU 62 detects the open / closed state of the second transport roller 342 (FIG. 4) and the second paper discharge roller 358 (FIG. 4) of the transport mechanism 34 (step S25). The second conveying roller 342 is pressed against the first conveying roller 341 or separated from the first conveying roller 341 by the closing operation and the opening operation of the roller opening / closing motor 72. The second paper discharge roller 358 is pressed against the first paper discharge roller 351 or separated from the first paper discharge roller 351 by the closing operation and the opening operation of the roller opening / closing motor 72. The controller 61 detects the open / close state of the second transport roller 342 and the second paper discharge roller 358 by determining the operation state of the roller open / close motor 72.
Then, the CPU 62 determines whether the second transport roller 342 and the second paper discharge roller 358 detected in step S25 (step S26), and either or both of the second transport roller 342 and the second paper discharge roller 358 are determined. Is in an open state (step S26; No), the motor driver 68 is controlled to cause the roller opening / closing motor 72 to perform a closing operation, and both the second transport roller 342 and the second paper discharge roller 358 are closed. (Step S27), the process proceeds to Step S28. If both the second transport roller 342 and the second paper discharge roller 358 are in the closed state (step S26; Yes), the CPU 62 proceeds to step S28.

  In step S28, the CPU 62 controls the motor driver 68 to operate the gap adjustment motor 75, and adjusts the gap between the recording head 30 and the continuous paper to a predetermined reference amount. This reference amount is, for example, the maximum value in a range where there is no mechanical problem of the recording mechanism unit 20. When the ink ribbon 51 is moved between the recording head 30 and the continuous paper, such as when the ribbon cartridge 50 is replaced, it is preferable that the gap between the recording head 30 and the continuous paper is large, and a ribbon jam has occurred. Even in this case, it is preferable that the gap is larger in view of the ease of work for removing the ribbon jam thereafter. Subsequently, the CPU 62 controls the motor driver 68 to operate the carriage drive motor 32, and moves the carriage 28 to the retracted position (step S29). The retracted position is, for example, a position closest to the left side frame 22 side, and is a position suitable for work for exchanging the ribbon cartridge 50 or the like. Then, the CPU 62 controls the motor driver 68 to stop the operations of the carriage drive motor 32, roller opening / closing motor 72, transport motor 73, ribbon drive motor 74, and gap adjustment motor 75 (step S30). This process ends.

  In the ribbon jam handling process shown in FIG. 17, the CPU 62 refers to the alarm factor register and the ribbon jam occurrence factor flag is set to 1, that is, an abnormality has occurred in the winding state of the ink ribbon 51. When the supply of power to the motor driver 68 is stopped by the ribbon take-up detection unit 69, the supply of the driver driving power P to the motor driver 68 is restored. As a result, when the winding operation of the ink ribbon 51 occurs and the operation of the dot impact printer 10 is stopped, the dot impact printer 10 shifts to a state where it can operate quickly, and the problems associated with the ink ribbon 51 are resolved. Once the work is done, normal operation can be resumed. Further, after the supply of the driver driving power P to the motor driver 68 is restored, the second transport roller 342 and the second paper discharge roller 358 are closed, and the gap between the recording head 30 and the continuous paper is changed. Therefore, for example, recovery work for removing the cause of abnormal winding of the ink ribbon 51 such as removal of the entangled ink ribbon 51 and replacement of the ribbon cartridge 50 can be performed very easily. In addition, when the carriage 28 is moved to the retracted position, the recovery operation can be performed more easily.

  Further, in the ribbon jam handling process, if the ribbon jam occurrence factor flag is not set to 1 in the alarm factor register, the CPU 62 does not restore the supply of the driver driving power P to the motor driver 68. For this reason, when an abnormality occurs in a portion other than the ink ribbon 51 and the supply of the driver driving power P is stopped, the CPU 62 does not restore the driver driving power P. As a result, the driver drive power supply P is restored when a serious failure or the like that should not restore the driver drive power supply P occurs, and each part of the dot impact printer 10 is not damaged. Since the process of FIG. 17 is performed only when a winding abnormality occurs, an appropriate operation can be performed even when other failures occur while enabling early recovery when the abnormality of the ink ribbon 51 occurs.

  The embodiment described above shows one embodiment of the present invention, and it is needless to say that the embodiment can be arbitrarily modified and applied within the scope of the present invention. For example, in the above-described embodiment, the configuration in which continuous paper is used as the recording medium is illustrated, but cut paper may be used. In the above embodiment, the ribbon driving unit 37 disposed on the right side frame 21 is used to drive the ribbon cartridge 50 mounted from the right side frame 21 to the left side frame 22. The present invention is not limited to this, but can be applied to an on-carriage type configuration, that is, a configuration in which the ink ribbon cartridge mounted on the carriage 28 moves together with the carriage 28. Further, other detailed configurations can be changed as appropriate without departing from the spirit of the present invention.

1 is an external perspective view of a dot impact printer according to an embodiment of the present invention. It is a rear view of a dot impact printer. It is a perspective view which shows the structure of a recording mechanism part. FIG. 4 is a cross-sectional view of a recording mechanism section taken along line AA ′ in FIG. 3. It is a top view of a dot impact printer. It is a top view of a dot impact printer. It is a perspective view which shows the structure of a ribbon drive unit. It is a perspective view which shows the structure of a ribbon drive unit. It is sectional drawing which shows the structure of a ribbon drive unit. It is an external appearance perspective view which shows the structure of a ribbon cartridge. It is a top view of a ribbon cartridge. It is a cross-sectional view of a ribbon cartridge. It is a principal part enlarged view of FIG. It is sectional drawing of the ribbon cartridge in the BB 'line of FIG. It is a functional block diagram of a control part with which a dot impact printer is provided. It is a flowchart which shows a ribbon jam detection process. It is a flowchart which shows a ribbon jam handling process.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Dot impact printer (recording apparatus), 20 ... Recording mechanism part, 30 ... Recording head, 32 ... Carriage drive motor (carriage drive means), 37 ... Ribbon drive unit (winding mechanism), 38 ... Ribbon winding shaft, DESCRIPTION OF SYMBOLS 40 ... Winding detection shaft, 41 ... Winding sensor, 50 ... Ribbon cartridge, 51 ... Ink ribbon, 56 ... Winding roller, 58 ... Driven roller, 60 ... Control part, 61 ... Controller, 62 ... CPU (control means) , 63 ... ROM, 64 ... RAM, 66 ... power supply control unit, 68 ... motor driver, 69 ... ribbon take-up detection unit (stop control means), 71 ... power supply circuit, 72 ... roller opening / closing motor, 73 ... conveyance motor, 74: Ribbon drive motor, 75 ... Gap adjustment motor (gap adjustment means).

Claims (3)

The recording head includes a plurality of driving units including a carriage driving motor, a conveyance motor, and a gap adjustment motor that drive each unit, and the plurality of driving units and the recording head are controlled by a controller that executes a control program. In a recording apparatus that scans a recording medium on the recording medium, strikes a recording wire from the recording head, and records an image on the recording medium via an ink ribbon.
A driver for supplying power to the plurality of driving units based on a driver driving power source supplied from a power supply circuit;
A winding mechanism for winding the ink ribbon;
A stop control unit that detects an abnormality in the operating state of the winding mechanism, stops supplying the driver driving power to the driver without interposing the controller, and writes a value indicating the winding abnormality to a register; ,
Wherein the controller is returned to execute the process of referring to the value of the register for each predetermined time, to return the supply of the driver driving power to the driver if a value that indicates the winding abnormality value Processing,
A recording apparatus. In the return process, the controller returns the power supply to the driver , and further operates at least the gap adjustment motor to set the gap between the head of the recording apparatus and the recording medium to the ink. claim 1 Symbol placement of the recording apparatus, characterized in that shifting to the amount for the job to eliminate the abnormality in the winding state of the ribbon. 3. The recording apparatus according to claim 2 , wherein the controller operates the carriage drive motor to move the carriage to a predetermined retracted position, and operates the gap adjusting unit to expand the gap.

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