KR0140999B1 - Processing system with printer using exchangeable ink ribbon - Google Patents

Abstract

None.

Description

Processing system with printer using replaceable ink ribbon

1 is a block diagram of a word processing system showing a configuration of a processing system according to the present invention.

FIG. 2 shows the operation of the printer and printer controller of the word processing system shown in FIG.

3 is a partial cross-sectional view of the printer showing the operating mechanism of the printing head and carriage of the printer shown in FIG.

4 is a cross-sectional view on line A-A shown in FIG.

5A through 5E are flowcharts illustrating the operation of a word processing system in printing document lines on paper.

FIG. 6A shows the contents of the line buffer shown in FIGS. 1 and 2 when the sample character pattern of a line is printed on paper by a word processing system. FIG.

6B and 6C show steps in the printing of the sample characters shown in FIG. 6A.

6D is a diagram showing the printing result of sample character patterns according to one aspect of the present invention.

* Explanation of symbols on the main parts of the drawings

311: carriage 311c: carriage fingerboard

311e: leaf spring 312: stepping motor

313: head fingerboard 313a: printing head

315: guide shaft 320: belt

330 Bevel Gear 337

317,318,326,327,328: spur gear

The present invention relates to a processing system having a printer using a replaceable ink ribbon to print a document comprising letters, symbols, drawn lines or graphic patterns thereby.

In processing systems such as word processing systems, printers are used to print characters, symbols, graphic patterns, etc., on materials such as paper. Printers often use conventional ink ribbons embedded in cassettes as printing media. For example, as described in US Pat. No. 4,387,380, the thermal transfer printing system uses a conventional ribbon cassette, wherein the polyester ribbon tape is a pig, such as carbon black, dispersed in a binder that is susceptible to heat. It is covered with a piece or die.

In printing, when using a conventional ink ribbon, the ink ribbon has to be replaced with a new one if the ink ribbon runs out from reading to the end portion. Therefore, a printer using a conventional ink ribbon has a built-in ribbon-end detector for detecting the end of the ink ribbon (hereinafter referred to as the end of the ink ribbon), so that printing can be stopped when the ink ribbon is exhausted and the processing system can be Instruct the operator to replace the ink ribbon with a new one. One type of ribbon-end detector with a photo conpler is described in US Pat. No. 4,387,380, and another type of ribbon-end detector is described in Japanese Patent No. 58-59886.

For example, at the end of the ink ribbon, the base film is covered with metal. Thus, the pigment-coated portion of the ribbon may not reflect light, while the metal-coated portion may reflect light.

By providing light emitting diodes for photodiodes and phototransistors for optical sensors in the printer, the phototransistors can detect light rays from light emitting diodes reflected by the metal-coated portions of the ink ribbon. Only when the ribbon-coated portion of the ribbon comes in front of the light emitting diode and the ink ribbon is used up, the printing system detects the light beam from the light emitting diode and generates a detection signal, so the printing system can recognize the depletion of the ink ribbon so that the phototransistor Printing is interrupted by a sense signal from the. Then, after printing is stopped, the operator can replace the used ink ribbon or ink ribbon cassette.

However, in a conventional processing system, when the ink ribbon runs out in the middle of printing a document page line, after the used ink ribbon is replaced with a new one, the document is printed-started, such as the headline of the page or the head of the unread line. It should be printed again from the position. Thus, paper with parts of document pages already printed must be dumped and replaced with a new one.

It is a first object of the present invention to provide a processing system having a printer using interchangeable printing materials in which printing stops at an intermediate position of the line when the printing material runs out in the middle of the line printing of a character or image pattern. In this way, the printing material can be restarted from the intermediate position after replacing the used printing material with a new one.

According to a second aspect of the present invention, in providing a processing system having a printer using replaceable printing material, after printing is stopped in the middle of a printed document line to replace the used printing material with a new one, line printing This restart allows the already printed line portion to be connected to the remaining portion cleanly.

It is a third object of the present invention to provide a processing system having a printer using replaceable printing materials so that when the printing materials are exhausted and replaced with new ones, the used printing materials are easily exchangeable.

Memory means for storing print information; Printing means for printing the print information stored in the memory means, i.e., printing means for printing the print information using an exchangeable printing material; Printing means for incorporating detection means for detecting whether the printing material is used up; Control means for controlling the printing means; In response to the detection of the used printing material, the control means for storing the position data in accordance with the position stopped when the printing material runs out during printing of the print information; According to the stored position data, after the used printing material is exchanged, the above-described object is provided by providing a processing system having control means for restarting the printing means for connecting the remaining portion of the print information and the portion for which the print information is printed. Can be achieved.

Other objects and features of the present invention will be described in detail with reference to the drawings.

1 shows a configuration of a word processing system according to the present invention.

The word processing system incorporates a central processing unit or microprocessor (CPU) 10 for controlling system operations for executing document writing, editing, printing, and the like.

The ROM 110 is connected to the CPU 10 via a bus line and loads a program for operation executed by the CPU 10.

A print control program for controlling to print a document on paper is loaded in the area 111 of the ROM 110. Other programs for controlling other system operations are loaded into area 113 in ROM 110. Since these programs are programs commonly used in word processors, description thereof will be omitted.

The keyboard device 100 is connected to the CPU 10 by a bus line that inputs character code, graphic patterns or other document data and command codes for the drawn lines into the word processing system.

The keyboard device 100 incorporates character keys and control keys (both not shown in FIG. 1). Letter keys correspond to alphabetic letters, numbers, and symbols, such as S,%, or C. Characters are used to enter characters, which constitute a document in the processing system. The control key incorporates several command keys (such as deleting, copying, and moving a string) that instruct the CPU 10 to execute a cursor control key, an execution key, and an edit operation. When a key on the keyboard device 100 is pressed, the keyboard device 100 generates a key code corresponding to the key and transmits the key code to the CPU 10. Keyboard device 100 is described in US Pat. No. 4,609,908. In the present invention, an execution key is used to replace an ink ribbon which is a server.

The RAM 20 is also connected to the CPU 10 via a bus line, and loads character codes and character data input from the keyboard device 100. The character code and the document data constituting the document are loaded into the character string data area 21 of the RAM 20. The RAM 20 incorporates a control raster DUDD station 23 for loading control data, which needs to print a document in accordance with the present invention. The printer 30 is connected to the CPU 10 via the printer controller 40. The bus line connects the printer controller and the CPU 10. The printer 30 is a thermal printer as described in US Pat. No. 4,387,380 and US Pat. No. 4,712,115. 3 shows a part of the printer 30, and FIG. 4 is a cross-sectional view taken along the line A-A of FIG.

The printer 30 has a carriage 311 carrying an ink ribbon cassette. This ink ribbon cassette is shown in US Pat. No. 4,712,115 and incorporates two reels installed to rotate. The polyester film wrapped in a pigment is wound around one reel, and the other reel rolls up the used part of the film. As mentioned above, the ends of the film are covered with metal for ribbon end detection. This ink ribbon cassette is provided on a carriage base plate 311c. At this time, the reel drive shaft being rotated is inserted into the reel for the spent ribbon portion, so that the reel is rolled up by the clutch 311a to wind up the scrapped ribbon portion.

The head board 313 having the thermal printing head 313a is disposed on the carriage 31. The thermal printing head 313a faces the platen 337 of the printer 30. The ink ribbon passes between the platen 337 and the thermal printing head 313a, ie from right to left in FIG. A sheet of paper is printed on the paper by the space 337a and passes upward in FIG. 4 through the space between the ink ribbon (if the cassette is attached to the carriage) and the platen 337. Paper is fed by a paper feed motor. Paper feed mechanisms are well known as described in US Pat. Nos. 4,712,115 and are omitted in FIGS. 3 and 4.

The thermal printing head 313a has eight types of thermal fins arranged in columns (xhdtkdwjrdmfh ink ribbon supply direction), each pin dissolving a film-like pigment and dissolved on paper. It heats up in response to the received heat signal (HEAT SING shown in the second) which causes the pigment to be placed. Pigments lying on the paper again condense on the paper. Thus, by transferring the thermal signal to the corresponding thermal pins, eight dots in the column can be printed on paper at the same time. These are described in more detail in US Pat. No. 4,387,380.

As shown in FIGS. 3 and 4, the carriage 311 is held by guide shafts 315, 316. The base of the carriage 311 is promoted toward the guide side 315 by a leaf spring 311a for preventing the carriage 311 from shaking.

The front portion of the carriage 311 is fixedly attached to its sgckfnf mating-shaped flexible belt 320. The belt 320 extends between the spur gears 319, 322, 323, 324 and the pulley 321 installed on the actuator side of the stepping motor 312. 319, 322, 323, and 317 are provided on the actuator side of the stepping motor 321. The spur gear 318 meshed with the gear 317 is provided below the gear 319. As shown in FIG.

Therefore, the driving force generated by the stepping motor 312 is transmitted to the belt 320 attached to the carriage 311 through the gears 317, 318, 319, so that the stepping motor 312 is guided ( The carriage 311 may be moved back and forth along the 315 and 316. The stepping motor receives the machine / instruction signal ster / dir from carriage control firmware fw 43. The STEP signal defines the number of steps as the stepping motor 312 rotates. The DIR. Signal defines the direction in which the stepping motor 312 rotates. In this way, the volume and direction of carriage movement are controlled by the STEP / DIR. Signal from the carriage control FW.

As shown in FIG. 4, the head fingerboard 313 is pushed in the direction away from the print plate 337 by a spring 311C connected between the carriage 311 and the head fingerboard 313. The head support plate 313 DS can be moved in the direction of the platen 337 and its opposite direction by the head up / down mechanism described next. When the head paper plate 313 having the head 313a is moved in the direction of the printing plate 337, the head 313a is pressed against the printing plate 337 to push the ink ribbon and paper.

Thus, since the ink layer of the ink ribbon comes into contact with paper, ink or pigment selectively melted on the heat pin of the head 313a is swept over the paper. Therefore, by scanning the carriage 311 with the printing head 313a from the left to the right in FIG. 3 without paper feeding, a column including eight dots, that is, dot patterns of lines, can be printed. The movement of the head 313a in the direction of the fundus fund 337 away from the printing plate 337 is considered to be the up of the head 3113a.

The head up / down mechanism incorporates the head up / down plate 325 and l-shaped portion 311d. As shown in FIG. 3, the head up / down plaid 325 can swing up and down near the guide side 316. The coil spring 336 is wound around the shaft 316 for pushing the head up / down plate 325 upwards. A tab of the head up / down plaid 325 rests on bar 335, which is rotated about axis 316. A bar 335 having a protrusion that engages a recess prints spirally on one of ldj 334. As the gear 334 is rotated, the bar 335 moves up and down by the protrusions, moving up and down the head up / down plate 325.

As the plate 325 moves up, the L-shaped portion 337 rotates clockwise in FIG. 4 and pushes the headboard 313 in the direction of the platen 337.

On the contrary, when the head up / down plate 325 is moved downward by the spring 311c, the head support plate 313 moves in a direction away from the platen 337 and the portion 311d moves counterclockwise. Go back. Gear 334 is also actuated by spindle motor 312. The spindle electric motor 312 is transmitted to the bevel gear through the spur gears 317, 318, 327, 328 intertwined with each other. When the bevel gear 329 meshes with another bevel gear 330, the gear 331 fixed on the same axis as the bevel gear 330 may be rotated by the stepping motor 312. The plate 332, which is in contact with the gear 333, is installed on the axis of the gear 330 so as to be movable relative to the gears 330 and 331. In FIG. 3, one of the gears 333 is placed behind the gear 331. Depending on the direction of rotation of the stepping motor 312, or the direction of rotation of the gear 331, one of the gears 333 is in contact with the gear 334. The notched surface of the gear 334 is partially scraped. Thus, if the gear 334 is rotated by one of the gears 333 in contact therewith, then the rotation of the stepping motor 312 of the gears by the same gear 333, the gear 333 and the gear 335 It can be controlled by head up / down movement with the movement of the helical recess on the gear 334 that follows. Therefore, the head up / down control firmware FW can control the head up / down mechanism which moves the head board 313 up and down by transmitting the appropriate STER / DIR signal to the stepping motor 312. Instead of the head up / down mechanism described above, the mechanism described in US Pat. No. 4,712,115 can be applied to the present invention.

As described in US Pat. No. 4,712,115, the ink ribbon is wound by a reel, which is the axis of the carriage 311 as the headboard 313 moves downwards as the carriage 311 moves to the right in FIG. It is operated by 311a. This ribbon reeling operation is performed by a gear mechanism (not shown in FIG. 3), where the actuator shaft 311a rotates counterclockwise in FIG. 3, and the gear receives rotational force from the belt 315. do. Thus, the ribbon portion exhausted after one column of dots printed by the head 311a is moved to the left by rotation of the reel on the actuator axis 311a, where the stepping motor 312 moves the carriage 311 down. It is moved to the right by one step with the fingerboard 313.

By arranging the light emitting diode and the phototransistor of the above-mentioned ribbon termination detector in the portion 314 of the carriage 311 shown in FIG. 3, the phototransistor can detect light rays from the light emitting diodes reflected by the metal-coated ribbon termination. have. As shown in FIG. 2, the ribbon end sign is generated by a phototransistor sent to flip-flop 434 to set the ribbon end flag. This ribbon end flag indicates 1 when the entire ink ribbon in the cassette provided on the carriage 312 runs out.

1, the display controller 70, the video ram (vram) 80, and the display device 90 visually display document data and messages loaded from a program into a character string data area of the RAM 20. Is connected to the CPU 10. Since the display controller 70, the VRAM 80, and the display device 90 are well known, detailed description thereof will be omitted.

Referring to Fig. 5E in Figs. 2 and 5A, the operation of the printer controller 40 can be known in detail. 2 is a block diagram illustrating the operation of such a system. 5 shows an operational flowchart of such a system in printing a line of documents.

The operation of the printer controller 40 consists of three firmware programs (FW) executed by the microprocessor in the printer controller 40, namely the print control FW 41, the carriage control FW 43 and the head up / down control FW. Obtained by (45). The print control FW uses the start position data register 411, the end position data register 412, and the head position data register 413 being printed, and according to the contents of the registers 411, 412, 413, The number of steps and the carriage moving direction for moving the carriage 31 to the position are determined.

When printing a document loaded in the RAM 20, the CPU 10 reads the character code data line by line from the line of the RAM 20, and then patterns the corresponding character dot pattern data according to each read character code data. Read from memory 5. In-line dot pattern data is written to the line buffer 60 by the CPU 10, as shown in FIG. 6A (step 511). In the case of printing a graphic pattern such as a drawn line, the CPU 10 generates dot patterns of a line forming the graphic pattern according to the graphpack pattern data loaded in the RAM 20. In the present invention, the addressed word of the line buffer 60 corresponding to one column of the line contains 8 bits, and the line buffer 60 has about 1500 words.

Then, the CPU 10 sets the printing start position data and the printing end data in the registers 411 and 412 (steps 513 and 515), respectively. A start position defining the start position of the carriage 311 in the head 311a. The data is down, and printing of dot pattern data of the line loaded in the line buffer 60 is started. In the example shown in FIG. 6A, the start position data indicates an address [6] of the buffer 60 which is a column. The end position data at the end of the printing of the line defines the end position of the carriage. The printing end position data indicates the addresser 22 of the line buffer 60. Instead of steps 513 and 515, the print control FW 41 itself audits all words in the line buffer from the first word (address 0) to the last word (address 1500), and the dot pattern data of the column starts printing. The address of the word that is first read into the position data and finally parsed into the printing end position data is determined. The head position data being printed is stored in the register 413. The data stored in the register 413 indicates the position of the carriage 311 in which the position of the carriage 311 is determined. As shown in FIG. 3, the printer 40 has a carriage zero position detector incorporating a light emitting diode 338 and a phototransistor that receives light from its left inner phase light emitting diode. The carriage 311 includes an extraction portion 311b between the light emitting diode 338 and the phototransistor 339, and when the carriage 311 is moved to the leftmost position, i. Block it. The contents of the register 413 are reset_ in response to blocking of the signal from the phototransistor 339. Thereafter, the contents of the register 413 are updated as the carriage 311 moves. Therefore, the print head position data stored in the register 413 incorporates the position of the carriage 311 in which the position of the carriage 311 is determined. The print control fw 41 determines the number of steps for moving the carriage 311 with the head 311a to the printing start position and the moving direction of the carriage 311 by using the head position data and the start position data being printed. (Step 517).

In this step 517, fw 41 subtracts the starting position data from the current head position data. The absolute value of the subtraction result matches the required number of steps, and the sign of the audit result matches the required direction of movement, minus minus is the downward direction and plus plus is the measurement direction. The fw 41 then carries the carriage control FW 43 with the determined step number data STEP NUM and direction data DIR. (Step 519). After the STER NUM, data is stored in the step number register 431 used by the FW 431, the carriage control FW 43 starts to be executed.

By executing the data stored in the gage 431 from the step 523 through the step 529, the carriage 311 brings the start position when the printing of the pattern E loaded in the line buffer 60 is started.

In this purity, the contents of the step number register 431 are down counted by one step each time the carriage 311 is moved by one step (step 523) (step 525). Then, the contents stored in the head position data register 433 being printed are similarly counted up or down one by one according to the moving direction of the carriage, and the right shift is +1 and the left shift is -1. (Step 527).

The print head position data register 433 of the carriage control FW 43 is reset by the same method as the register 431 of the print control FW 431, and stores the current head position data counted according to the carriage movement. do. Therefore, the Zeta stored in the register 433 always indicates where the carriage 311 is located. In step 529 in which the contents of the register 431 are checked, if the stored data is 0, that is, the carriage 311 is set on the start position, step 531 is executed or another step 523 is executed again. . After the carriage 311 is set on the start position, the contents of the register 433 are set in the register 413 used by the print control FW 41 (step 531).

Thus, the data stored in the register 413 indicates the current carriage / head position. Next, the print control FW 41 is required to print the entire pattern) DMF data stored in the line buffer 60 by subtracting the start position data of the register 411 from the end position data of the register 412. The total number of steps of carriage movement is calculated (step 533). At this time, the print control FW 41 sets the number of steps and initial line buffer address data calculated according to the start position data of the register 412 in the registers 431 and 437, respectively.

Since it is printed by the head 313a performed from left to right of the paper in the printer 30, the DIR, signal is set to indicate the right side. The initial line buffer address data stored in the register 437 defines the word address of [6] in the example shown in FIG. 6A, that is, the column of pattern data is first stored.

From step 537, line printing starts. The print control FW 41 checks the ribbon end flag from the flip-flop 434 (steps 537 and 539) whether or not it is a ribbon cassette with a ribbon with an unused ink ribbon (steps 537 and 539). Go to step 600 to request the operator of the system to exchange the ribbon cassette for a new one. In step 600, the print control FW 41 transmits the ribbon end state data to the CPU 10 indicating that the ribbon cassette with the unused ink ribbon is not set. In response to the status data, the CPU 10 displays a message to change the ribbon cassette (step 602). Wait until the execution car of the CPU 10 SMS keyboard device 100 is pushed back by the operator. Then, the print control FW 41 is instructed to execute steps 537 and 539 (step 604). When the ribbon end flag is not set in step 539, the print control FW 41 sends a head down signal DOWN to the head up / down control FW 45 (step 541).

The FW 45 then moves down the head support plate 313 by the above-described method.

Subsequently, print operation is started by the carriage control FW 43. The pattern data of the column is read from the line buffer 60 in accordance with the address data stored in the FW 437, and the column signal HEAT SIGN is transmitted to the head 313a in accordance with the read pattern data. Thus, a column of dot patterns is printed on paper. The contents of the register 431 are counted down one by one at step 545. If the data indicates zero, i.e., the printing of the line is ended and the control sequence goes to step 549, the end of one line printing is announced at the CUP. If another line is printed, the procedure is executed again from step 2 (511). Conversely, if the step number data stored in the register 4312 is not 0 at step 547, step 551 is decomposed next, and the carriage 311 is moved one step to the right of the paper, and the used ribbon The portions are simultaneously wound by the steps of the ribbon cassette one by one. Then, the contents of the register 433 and the contents of the register 437 are both counted up one by one (step 553), and it is checked in step 555 whether the ink ribbon is used up. If the ribbon portion remains, the control sequence returns to step 543. Otherwise, by performing steps 557 to 577, the printing is temporarily interrupted in the middle of one line printing, and the used ink ribbon is exhausted. After the new one is replaced, it restarts from the stopping point of the line.

In step 557, the carriage control fw 43, which informs the print control fw 41 of the printing of the line, is stopped in the middle for the replacement of the ink ribbon cassette, and the FW 43 then registers 433 to the register 413. Send the contents of). Therefore, the data stored in the register 413 indicates the printing intermediate position in the middle of the line where the carriage stays. In the example shown in FIG. 6B, after the column dot pattern written in the word of the line buffer 60 addressed to [19] is printed on the paper and moved one step to the right with the carriage 311 (carriage position [20]), the ink ribbon is used up and printing is stopped. Next, the print control FW 43 ups the head fingerboard 313 by controlling the head up / down control FW 45 (step 558). In step 559, the ribbon end state data described above. And the ribbon end position data advance from the print control fw 43 to the CPU 10. If printing is restarted from the next column, there is a tendency to print the space between the printed column and the next column because of the inaccuracy of the print mechanism.

Therefore, the ribbon end position data in the present invention is the same as [current position data-1], namely, [19] in the example shown in FIG. Therefore, in the printing of the remaining lines, the dot pattern for the last column of the line where the same pattern is printed is printed again on the same column on paper. The CPU 10 loads the ribbon end position data (= [19]) transmitted from the print control FW 41 into the RAM 20 (step 561). In the next step 563, the CPU 10 The carriage 311 sets carriage center position data representing the substantial center of the entire scan line to the start position data register 411.

This step 563 is for moving the carriage 313 toward the center of the housing of the printer so that the operator can easily replace the used ink ribbon cassette even when the carriage 311 is stopped at the close side of the printer housing. By executing 571 at step 565, the carriage 311 is moved around the printer housing. Operation by 571 at step 5656 is similar to the far field of step 517 and 531 described above. After the carriage 311 is moved to the center position, the CPU 10 displays the message described in step 602 to request an operator to exchange the used ribbon cassette for a bird feather (step 573). By placing the execution key of 100), the ribbon cassette to be exchanged is notified to the CPU 10, and the CPU 10 transfers the ribbon end position data in the RAM 20 loaded at step 561 to the start position data register 411. Set to. Then, returning to step 517, printing is restarted. Since this data stored in the register 417 represents the final column of the line in which the dot pattern is preferentially printed for printing (in the example [19]), the remaining dot patterns of the line shown in FIG. Printed by Reprinted second-hand print operations. By subtracting burner 1 from the ribbon end position data at step 559, the column dot pattern finally printed on the printing first is overprinted in the current printing, as shown in FIG. 6C. Therefore, as shown in FIG. 6D, the line dot patterns are printed in priority printing and the space up is continuously printed in the printing in which both remaining line dot patterns are restarted.

As described above, even when the ink ribbon is running out in the middle of the printed document on the paper printed on the paper according to the present invention, the printing of the document is performed after the replacement of the printed paper after replacing the used ink ribbon with a new one. The document part can be restarted.

In the present invention described above, the CPU 10 sets the register 411 for ribbon end position data. Instead of these steps. The following modifications can be applied. When the ink ribbon is exhausted, the print control FW 41 has a space of all zeros from the word address [0] to the word before the last printed word according to the ribbon end position i [current head position data 1-1]. The data bits are locked to the line buffer 60. In the example shown in FIG. 6B, the contents of words addressed from 0 to 18 can be changed for spatial data. In this case, the rest of the contents of the register 411 are not changed and line printing is restarted. In this case, the carriage 311 is moved back to the print start position of the line, and printing is restarted therefrom. However, since the last printed column is removed and written to the preferentially printed subboom of the spatial data line buffer, only the remaining portion shown in FIG. 6C is printed.

The recording of the spatial data in the line buffer 600 is performed by the carriage control FW 43 whenever the carriage control FW 43 reads the pattern data therein. In the present invention, shown in FIGS. As the printing is performed by repeating the carriage control FW 43 printing the line from the head position to the printing, ribbon end position data is not necessary in this system.

Numerous modifications and cotton of this hoof are possible in the aforementioned collinear. Therefore, within the scope of the appended claims, the invention may be practiced otherwise than as herein described.

Claims (3)

Memory chatter for storing print information; A printing means for printing the print information stored in the memory means, the printing information being printed using the print replaceable printing material, and the detecting means for hiding the printing material; Control means for controlling the printing means, wherein the control means stops the printing means for printing the print information when the printing material runs out during printing of the print information in response to the detection of the printing material that has run out, And to restart the printing means for storing the position data corresponding to the position where printing was interrupted, and connecting the printed material which has been exhausted according to the stored position data to the print information after the exchange, and for printing the remaining portion of the print information. Processing system, characterized in that. 2. The printing apparatus according to claim 1, wherein said printing means includes a printing head means for printing a line of print information and a carabiner means for moving a printing head along the line, wherein said control means comprises a remaining portion of printing data. And a carriage means for moving the printing head to a position determined by the data position before printing of the substrate is started. 2. The apparatus of claim 1, wherein the memory means stores pattern data of a line of print information and the control means is further configured to print the printed pattern data according to the position data before printing of the remaining portion of the printing data is started in the memory means. Processing system, characterized in that the deletion.

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