JPH0576431B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention automatically adjusts the gap between a print head and a platen (or medium) in order to print on various media having different paper thicknesses. The present invention relates to a printer equipped with an automatic paper thickness adjustment mechanism, and particularly relates to an automatic paper thickness adjustment mechanism that performs optimal gap adjustment by controlling the print head position.

(Prior art) In order to perform proper printing in an impact printer using a wire dot head, it is necessary to have a certain gap between the tip of the wire dot head and the printing surface of the medium due to the wire stroke limitations of the wire dot head. There is. Generally, this gap is adjusted before printing to accommodate the paper thickness of the media. Therefore, when printing on continuous paper having a certain paper thickness, gap adjustment only needs to be performed once before printing, and there is no particular problem in terms of printer operability.

On the other hand, when a printer prints forms,
The paper thickness of each form is different due to the difference in the number of copies, or the paper thickness of the front half and the back half of one page of passbooks is different, so it is necessary to adapt to these paper thicknesses each time. Gap adjustment is performed automatically. Some of the automatic paper thickness adjustment mechanisms that adjust the gap described above mechanically move the print head or platen, but in this case, the print head is moved to adjust the gap between the print head and the platen (or medium). The items to be adjusted will be explained below.

FIG. 7 is a schematic diagram showing a conventional automatic paper thickness adjustment mechanism. As shown in the figure, this automatic paper thickness adjustment mechanism is comprised of a print head 1, an assembly 2, a transmission mechanism 3, a motor 4, and a spring mechanism 5. The print head 1 is integrally attached to an assembly 2 that is movable in the vertical direction, and is mechanically connected to a motor 4 via a transmission mechanism 3 that engages with the assembly 2. The motor 4 is a power source for moving the assembly 2, and rotates forward or reverse based on a command from a control section (not shown). Although motor 4 is a DC motor with a timing generator,
The motor is not limited to this, and a pulse motor may also be used. The transmission mechanism 3 includes a gear 31 that engages with the rotating shaft of the motor 4.
and a cam 32 installed coaxially with the gear 31.
and an actuating part 33 that engages with the cam 32 and rotates in the vertical direction with one end using the other end as a fulcrum, and one end of this actuating part 33 also engages with the assembly 2. Further, a spring mechanism 5 having one end connected to the platen 6 is attached to the assembly 2, and this spring mechanism 5 always biases the assembly 2 in the direction of the platen 6 (downward). Here, for example, when the motor 4 rotates forward in response to a command from the control section, this rotation is transmitted to the assembly 2 via the transmission mechanism 3, and the assembly 2 moves upward against the spring mechanism 6. As a result, the gap between the print head 1 and the platen 6 widens (hereinafter referred to as a head-up). or,
When the motor 4 reverses, the operating part 33 of the transmission mechanism 3
Assembly 2 moves downward with one end of
After a predetermined rotation of the actuating part 33, it is released from the transmission mechanism 3 and further moved downward by the spring mechanism 5. As a result, the gap between print head 1 and platen 6 becomes narrower. (Hereinafter, this will be referred to as head-down).

The gap adjustment described above, that is, the movement of the print head, is normally performed in accordance with each of the media processing modes of the printer, such as suction/ejection mode, print mode, and line feed mode. This will be explained in detail below. First, in the intake/exhaust mode, the gap is adjusted to be greater than or equal to the maximum paper thickness used in the printer because the print head must be lifted off the media. Therefore, the printing head is raised as described above, and is mechanically held by stopping the rotation of the motor 4. Also, in the new line mode, the print head must be lifted above the medium, so the gap is adjusted and maintained in the same way as in the suction/ejection mode.

In the print mode, in order to make the print head 1 ready to print on the medium, the forcibly held print head is released from the transmission mechanism 3 by the rotation of the motor 4, moves its head down, and is pulled down by a predetermined amount of gap. hold. This predetermined amount is approximately 0.2 mm in addition to the thickness of the ink ribbon since it is included between the print head and the media. The gap is maintained by attaching a gap adjustment mechanism called a media follow to the tip of the print head. This media follow is a protrusion mechanism that protrudes a certain amount from the tip of the print head toward the printer, and maintains the predetermined gap by bringing this protrusion into contact with the surface of the medium. At this time, differences in paper quality of the media are absorbed by a constant bias of the spring mechanism 5 applied to the platen 6. Further, a guide level may be provided in order to eliminate various problems (for example, jamming) when the media follow directly contacts the medium.

When printing multiple lines with a printer equipped with the automatic paper thickness adjustment mechanism configured as described above, the gap can be set to suction mode, print mode, line feed mode,
The print head moves in a manner that corresponds to the print mode, . . . , and ejection mode.
Here, FIG. 8 shows a state diagram of the printing head when printing on a bankbook, and FIG. 9 shows a processing time transition diagram during printing. In Fig. 8, since printing is performed on the passbook 20 whose paper thickness is different between the body half and the back half, the position (gap) of the print head in the intake/discharge, line feed mode, and print mode is adjusted to correspond to each paper thickness. I know what you're doing. Further, as mentioned above, it can be seen from FIG. 9 that the print head changes in accordance with each mode.

(Problems to be Solved by the Invention) However, the printer equipped with the automatic paper thickness adjustment mechanism configured as described above has the following problems.

When printing on media with different paper thicknesses within a single page, such as a passbook, it is necessary to perform gap adjustment to correspond to the paper thickness each time before printing, and this increases the processing speed of the printer. This has resulted in a wide decline (see Figure 8). Also, when printing on a variety of media, if you set the line feed mode gap to the maximum paper thickness, the automatic paper thickness adjustment time of the print head (the time the print head heads down) when printing on thin media becomes a complete waste of time. I get used to it. This is because, as can be seen from FIG. 9, the gap at line feed is too wide. Furthermore, when moving the print head faster when moving from suction mode or line feed mode to print mode in order to shorten the processing time, in the case of copy paper, when the media follower attached to the tip of the print head collides with the paper, The pressure increases, causing stains on copies. For this reason, the moving speed of the print head is limited to a certain fixed value, which also hinders the increase in processing speed.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems and provide a high-performance printer with improved processing speed by controlling print head movement for gap adjustment of an automatic paper thickness adjustment mechanism. .

(Means for solving the problem) According to the first invention of the present application, the gap between the platen, the print head for printing on the medium placed on the platen, and the print head and the medium changes. A printer having a displacement mechanism for displacing the print head in such a manner has the following configuration.

That is, during suction, there is a print position detection means that detects the optimum print position of the print head determined according to the thickness of the medium, and a line feed position of the print head located between the home position of the print head and the optimum print position. The displacement mechanism is controlled so that the print head is at the optimum print position in the print mode and at the line feed position in the line feed mode.

Further, according to the second invention of the present application, the passbook/outside-passbook detection means detects whether the medium to be printed is a passbook, and the center hold position detection means detects the center hold position of the medium. A print position detection means detects the optimum print position of the print head determined according to the thickness of the medium during suction, and a line feed position of the print head located between the home position of the print head and the optimum print position is used for optimal printing. The displacement mechanism controls the print head so that it is at the optimum printing position in print mode and at the line feed position in line feed mode, but when the medium is , and if a line break is to be made over the center hold position of the passbook, the print head is moved to the home position.

(Function) According to the first invention, the medium to be printed is sucked in when the printer is in the suction mode, and the print head is displaced from the home position by the displacement mechanism. At this time, the print position detection means includes, for example, a pressure sensor attached to the tip of the print head that contacts the medium and detects its position, and determines the optimum print position of the print head based on the output from this pressure sensor. demand. Therefore, in the print mode, the displacement mechanism is controlled in accordance with the detected optimum print position to control the print head position. In addition, the line feed position calculation means calculates the line feed position where the tip of the print head is slightly away from the medium.
Calculate from this optimal printing position. This line feed position is far away from the home position and is quite close to the print position. Therefore, in the line feed mode, the displacement mechanism is controlled in accordance with the calculated line feed position to control the print head position.

As described above, according to the first invention, when a line feed occurs, the print head is displaced to a line feed position that is far in front of the home position and is determined according to the actual thickness of the medium, making it possible to print on thin media. Even in this case, the time required for the print head to move from the line feed position to the print position can be shortened, and as a result, the overall print processing time can also be shortened.

According to the second invention, whether or not the inhaled medium is a passbook is determined by the passbook/outside-passbook detection means, which is means for detecting the shape or size of the medium or the magnetic tape attached to the passbook. detected.
If the medium is detected to be a bankbook, it is determined based on information from the center hold position detection means whether printing has been performed beyond the center hold position of the bankbook. As a result, if a line feed is not made beyond the center hold position, the print head is displaced to the same line feed position as in the first invention, but if a line feed is made beyond the center hold position, the print head is displaced. is displaced to the home position.

In this way, according to the second invention, in addition to the above-mentioned advantages of the first invention, even when printing on media with different paper thicknesses within one page, such as a bankbook, the paper thickness can be adjusted each time. The advantage is that there is no need to adjust the print head position at the time of line feed.

(Example) Hereinafter, an example of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic diagram showing an automatic paper thickness adjustment mechanism of a printer according to an embodiment of the present invention. As shown in the figure, the automatic paper thickness adjustment mechanism according to this embodiment is as follows:
In addition to the conventional printer, there is a sensor 7 for detecting the home position of the print head 1, a pressure detection mechanism for detecting whether the tip of the print head 1 has contacted the medium (presence or absence of the medium), and a print head (not shown here) for printing. A medium discrimination sensor for discriminating the type of medium is provided. The home position detection sensor 7 is fixedly installed on the operating section 33 of the transmission mechanism 3, and detects the home position of the print head 1 by detecting the presence or absence of the operating section 33 that is movable in the vertical direction. The pressure detection mechanism has a pressure sensor 8 attached to the tip of the print head 1 to detect the presence or absence of a medium. The pressure sensor mounting position of this pressure detection mechanism is
Any other easy-to-install location may be used as long as the mechanism transmits pressure from the tip of the print head, but in this case, the mechanism should be a movable type that does not interfere with the gap between the print head and the medium during printing. Further, the pressure detection mechanism only needs to determine whether or not the tip of the print head 1 has come into contact with the sucked medium, and the magnitude of the pressure value does not matter. The medium discrimination sensor is, for example, a passbook/outside passbook detection sensor (hereinafter referred to as passbook/outside passbook detection sensor), and generally uses a magnetic tape attached to a passbook, a type code (I/D code) written on the passbook, or This is to determine whether a passbook is a passbook or not based on the shape or size of the passbook. The outputs of the home position detection sensor 7, the pressure sensor 8, and the passbook/external passbook detection sensor are supplied to a print control section to be described later (see FIG. 2).

Next, the operation of the automatic paper thickness adjustment mechanism according to this embodiment will be explained. FIG. 2 shows a block diagram of the automatic paper thickness adjustment mechanism. The type of medium to be printed is specified to the print control section 11 from the passbook/outside-passbook detection sensor 9 or the upper control circuit 10. Further, printing can be specified from the upper control circuit 10 to the print control section 11. When the print control unit 11 receives this print designation and medium type designation, the print control unit 11 responds to the suction, print, line feed, and ejection modes by inputting the home position detection sensor 7, timing pulse, pressure sensor 8, etc. motor 4, line feed motor 12,
Controls the rotation of the print head space motor 13. (In the figure, BLF is backline feed, BSP
is the backspace signal. In this embodiment, the rotational control of the motor 4, that is, the head up-down control of the print head, differs depending on whether the medium to be printed is a bankbook or a medium other than a bankbook. For this reason, first, the head up-down operation of the print head will be explained with reference to FIGS. 3 and 4 in the case where it is detected to be outside the bankbook (when printing on a medium of constant paper thickness).
FIG. 3 is a diagram showing head up-down of the print head, with the vertical axis representing the number of motor rotation pulses and the horizontal axis representing time. FIG. 4 is a flowchart showing the processing procedure for head up-down control of the print head. Home position detection sensor 7
By detecting the actuating portion 33, the home position of the print head in the head-up state is determined. This state is the position (gap) of the print head in the intake/discharge mode. Note that this gap needs to be wide because a guide mechanism may be provided between the platen and the print head in order to prevent jamming of the media on the platen that is being sucked in and discharged.

Once the home position is determined, the medium is inhaled (step 100). Next, as the motor 4 rotates a predetermined amount, the printing head starts to head down (step 101), and when the actuating section 33 of the transmission mechanism 3 separates from the home position detection sensor 11 (step 102), the rotation of the motor 4 causes the print head to head down. The generated timing pulse is counted positively (step 103). When the print head continues to go down and an output indicating the presence of medium is generated from the pressure sensor 8 attached to the tip of the print head (step 104), the number of timing pulses at this time N
is saved, for example, in the A register (step 1).
05). The position at which this pressure sensor 8 detects the medium differs depending on the thickness of the paper, and in Figure 3, the detection position when the paper is thick like a passbook is indicated by N _A , and when the paper is thin like a ticket, N _B is indicated. ing. Next, A (register) - Δn ₁ (number of pulses) is stored in the B register, and A+Δn ₂ (number of pulses) is stored in the C register (step 106). This Δn ₂ specifies the amount by which the assembly 2 of the print head 1 is disengaged from the motor 4 and transmission mechanism 3 and switched to the spring mechanism 5.

To continue applying constant printing pressure to the media,
Further, the print head is moved down by Δn ₂ minutes, and the motor is stopped when the number of timing pulses N=C (step 108). This position (N _A +Δn ₂
FIG. 3) is the print head position (gap) in print mode, where printing is performed on the medium (step 109). When printing is to be performed with a new line (step 111 will be described later), the print head is moved up (step 112). At the same time, the pulses generated by the motor rotation are counted down (step 113). Subsequently, the print head is pushed up beyond the N _A point to the N _A -Δn ₁ point (Figure 3), that is, the number of timing pulses N = B (A - Δn ₁ ) (step 114), and at this time the motor is stopped. (Step 115). This Δn ₁ is specified as a small amount by which the tip of the print head lifts up from the medium and does not interfere with the paper feed operation. This position is the print head position (gap) in line feed mode.
Then, a line feed is performed by the line feed motor 12 mentioned above (step 116). After the line feed, the print head is moved down again (step 117), and the pulses generated by the motor rotation are incremented (step 118). Then, the print head is moved down again to the once memorized print mode position and printing is performed (steps 107 to 109).
After specified printing and change operations, printing ends (Step 1)
10), the print head is lifted up to the home position (step 119) and ejected. Incidentally, the aforementioned Δn ₁ and Δn ₂ can be varied in various ways in the bankbook/outside the bankbook and specified to the print control unit. (This may be set in advance.) Next, a case will be described in which the medium to be printed is a passbook. In this case, the paper thickness may be different between the front half and the rear half of the same page with the center hold section as the boundary, so it is necessary to recognize the position of the center hold. The center hold can be recognized based on the format of the passbook, for example. This is because the number of printed lines on one page of a normal passbook is fixed, 12 lines in the front half and 12 lines in the back half, a total of 24 lines, so by recognizing this number of printed lines, center hold can be recognized. can do. Therefore, when printing a passbook, center hold skipping processing is performed when printing occurs across lines 12 and 13.

Hereinafter, in the case of a bankbook, the head up-down operation of the printing head will be explained with reference to FIGS. When a jump occurs (step 111), the print head is moved up to the single home position (step 120), where a center hold jump line feed is performed. After the line feed, automatic paper thickness adjustment is performed again, and the following is Step 1.
The same processing as described above continues from 01.

Here, FIG. 5 shows a state diagram of the printing head during printing of a bankbook according to this embodiment, and FIG. 6 shows a processing time transition diagram during printing according to this embodiment. As can be seen by comparing FIGS. 5 and 6 with the aforementioned FIGS. 8 and 9, according to this embodiment, when printing passbooks 20 having different paper thicknesses on the same page, at line breaks, Since the gap corresponding to the paper thickness, that is, the position of the print head, is adjusted and maintained, it has become possible to eliminate waste in the amount of head up of the print head compared to the conventional method. Furthermore, since the head-up time of the print head is greatly reduced, the overall processing time can also be reduced significantly.

In this way, the automatic paper thickness adjustment mechanism according to this embodiment can flexibly and optimally set and adjust the print position and line feed position of the print head in accordance with the paper thickness of the printing medium.

(Effects of the Invention) As described in detail above, according to the first and second inventions, the effects are as follows.

In various processing modes (especially line feed mode),
An appropriate print head position can be provided depending on the paper thickness of the medium to be printed. Therefore, even when printing on a medium with a thinner paper thickness than in the past, the time required for the print head to move from the line feed position to the printable position can be shortened, and as a result, the overall print processing time can also be shortened. Furthermore, even when printing on media with different paper thicknesses within one page, such as a bankbook, there is no need to adjust the print head position (in print mode or line feed mode) depending on the paper thickness each time. Therefore, it is possible to provide a high-performance printer with improved processing speed.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram of an automatic paper thickness adjustment mechanism of a printer according to an embodiment of the present invention, FIG. 2 is a block diagram related to the operation of the automatic paper thickness adjustment mechanism shown in FIG. 1, and FIG.
4 is a flowchart showing the processing procedure for controlling the operation of the print head, and FIG. 5 is the state of the print head when printing a bankbook according to an embodiment of the present invention. Figure, 6th
7 is a schematic diagram of the automatic paper thickness adjustment mechanism of a conventional printer. FIG. 8 is a state diagram of the print head during conventional passbook printing. FIG. 9 is a processing time transition diagram during conventional printing. DESCRIPTION OF SYMBOLS 1... Print head, 2... Assembly, 3... Transmission mechanism, 4... Motor, 5... Spring mechanism, 6... Platen, 7... Home position detection sensor, 8...
Pressure sensor, 9...Passbook/outside passbook detection sensor.

Claims (1)

[Claims] 1. A platen, a print head for printing on a medium placed on the platen, and a displacement mechanism for displacing the print head so that the gap between the print head and the medium changes. a printer having: a print position detection means for detecting the optimum print position of the print head determined according to the thickness of the medium during suction; and a print position detecting means located between the home position of the print head and the optimum print position. and a line feed position calculation means for calculating a line feed position of the print head from the optimum print position, and the displacement mechanism includes:
A printer characterized in that the printer is controlled so that the print head is at the optimum print position in the print mode, and the print head is at the line feed position in the line feed mode. 2. A printer having a platen, a print head for printing on a medium placed on the platen, and a displacement mechanism for displacing the print head so as to change the gap between the print head and the medium, A passbook/extra-passbook detection means detects whether the medium to be printed is a passbook; a center hold position detection means detects the center hold position of the medium; and a center hold position detection means detects the center hold position of the medium; a print position detection means for detecting a predetermined optimum print position of the print head; and a line feed position for determining a line feed position of the print head located between the home position of the print head and the optimum print position from the optimum print position. The displacement mechanism controls the print head to be at the optimum print position in the print mode and to be at the line feed position in the line feed mode, but when the medium is a passbook and the print head is at the line feed position. A printer characterized in that when a line break is made over a center hold position of the passbook, the print head is controlled to be at the home position.