JPS63160866A - Rcording apparatus - Google Patents

Abstract

PURPOSE:To certainly guide paper to a printing position and to certainly exclude the paper after printing from the printing position, by reciprocally revolving a paper guide member for guiding the paper to be printed on the outer peripheral surface of a platen roller between the first position for guiding the paper to the printing position and the second position for guiding the paper at the time of printing. CONSTITUTION:When a movable type paper guide 27 is present at the position shown by a point C, the pin 25a of a pulley 25 is not engaged with the cam part 27b of the guide 27 and said paper guide 27 is held to the state being brought into contact with a paper guide 30 by the energizing force of a spring 37. In this state, the movable type paper guide 27 is brought upwardly to open a platen roller 22 and an ink jet head IJU. When the movable type paper guide 27 is present at the position shown by a point D, the pin 25a of the pulley 25 is engaged with the cam part 27b of the guide 27 and the guide 27 is held to a state revolvable in conjunction with the revolution of the pulley 25 against the energizing force of the spring 37. In this state, the movable type paper guide 27 is brought downwardly to block the space between the platen roller 22 and the ink jet head IJU.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a recording apparatus equipped with a feeding device for paper to be printed, and particularly to a recording device equipped with an automatic paper feeding device using cut paper.

[Prior Art] Conventionally, the method of separating paper one by one from a paper cassette and feeding the paper to a platen roller to perform printing has the advantages of ease of operation, low cost, and miniaturization of equipment. It has many advantages and many proposals have been made.

[Problems to be solved by the invention] However, in such conventional recording devices,
In all of these, there is a restriction that the width of the paper (the length along the direction perpendicular to the paper feeding direction) must be set constant. This restriction is necessary in order to wrap the paper around the platen roller without floating the paper, and this poses a problem in that the structure of the device becomes complicated and the device becomes larger.

Furthermore, a configuration has been proposed in which, when paper is pinched onto the platen roller, a pinch roller that is in pressure contact with the platen roller is released from the platen roller, either manually or automatically, to allow eight strands of paper to stick. However, even if such a configuration is adopted, it is difficult to completely wrap the paper around the platen roller, and there is a problem in that the wrapping requires a correction operation after the wrapping operation.

In addition, there is the problem that the paper may be damaged or skewed due to the impact when the pinch roller is pressed against the platen roller again after the winding operation, and the mechanism and control become complicated. There are also problems.

In particular, this tendency becomes more noticeable when the pressing force of the pinch roller against the platen roller is increased in order to improve printing accuracy.

This invention was made in view of the above-mentioned circumstances, and an object of the invention is to be able to reliably guide paper to the printing position without separating the pinch roller from the platen roller, and to guide the paper after printing. It is an object of the present invention to provide a recording device which can guide objects to be reliably removed from a printing position and which can simplify the structure of a mechanism for this guidance.

[Means for Solving Problem No. 1] In order to solve the above-mentioned problems and achieve the purpose, a recording device according to the present invention includes a platen roller rotatably provided around a predetermined rotation axis, and a platen roller rotatable around a predetermined rotation axis. A paper guide member is located on the outer periphery of the platen roller, is rotatably provided around the rotation axis of the platen roller, and guides the paper to be printed on the outer circumferential surface of the platen roller. a first position for guiding the image to the printing position;
It is characterized by a driving means that rotates back and forth between a second position and a second position for guiding the paper during printing.

[Function] In the recording device configured as described above, the paper is reliably guided to the print position by the paper guide member in the first position until it reaches the print position, and after printing, The paper guide member that has moved from the first position to the second position ensures that the paper is guided away from the printing position.

Further, since the paper guide member is configured to rotate coaxially with the rotation axis of the platen roller, the distance between the platen roller and the paper guide member is always kept constant, and
The drive mechanism for the paper guide member becomes simple.

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following, a printer device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

External Appearance> FIGS. 1 and 2 show external views of a printer main body 1 of the printer device. A small-sized cassette 2 is detachably attached to the front of the printer body 1. Further, on the front of the printer main body 1, a makeup M is provided adjacent to the right side of the cassette 2.
3 is attached so that it can be opened. When the makeup M3 is opened, the ink cartridge 10, the auxiliary operation switch system 12, etc. are exposed to the outside, as shown in FIG. This decorative lid 3 is locked in a closed state by a claw 3a thereof and a notch formed on the side of the printer main body 1 (not shown), and is locked by turning it lightly with your fingers in the direction of the arrow in FIG. It is constructed so that it comes off and becomes the open state shown in Fig. 2.

Further, on the front surface of the printer main body 1, a dust cover 4 for a paper feed port 11 is releasably attached above and adjacent to the cassette 2. This dust cover 4 has a claw portion 4a and is configured to be openable and closable in the same manner as the decorative lid 3. A dust cover switch SWI, which will be described later, is attached to the dust cover 4, so that it is possible to know whether the dust cover 4 is open or closed.

Further, on the front surface of the main body 1, a knob 5 for attaching and detaching the cassette 2 is arranged adjacent to the left side of the cassette 2. This knob 5 will be described in detail later. A power switch 6 is disposed above the attachment/detachment knob 5.

Further, a display 7 is provided on the upper left side of the decorative lid 3 described above. The display 7 includes a display section 7a that displays an abnormality in the paper supply system, a display section 7b that displays an abnormality in the ink supply system, a display section 7c that displays the print position A, a display section 7d that displays the print position B, A display section 7e for displaying the print position C is provided in a state covered by a dust cover 7f.

Further, on the right side above the makeup M3, there is a main operation switch 8.
9 are arranged. Here, reference numeral 8 indicates a print switch, and this printer switch 8 is provided with an LED 8a that indicates that the print switch has been pressed.

Note that reference numeral 9 is not related to the present invention, and therefore a description thereof will be omitted.

The ink cartridge 10 described above is shown in FIG.
By pushing in the direction of the arrow, it is connected to the inkjet head IJυ via a known needle or the like, and is configured to be detachable using a lever described later. Further, as shown in FIG. 2, the auxiliary operation switch system 12 includes a switch 12a for selecting a print position, and since the other switches are not related to the present invention, their explanation will be omitted.

<Internal Layout> FIG. 3 is a top view schematically showing the internal configuration of the printer main body 1, and shows the main layout.

The printer itself! A carriage system CR, which will be described later, is installed at the back left of the interior, and this carriage system CR is responsible for the inkjet head! JU is main scanned. A paper feed system PF is disposed on the front side of the carriage system CR. This paper feed system PF is a platen roller 22
, paper feed roller 18, paper feed motor M2, paper feed motor M1
The details will be described later.

Further, a pump system PU is disposed in the center of the printer body 1. This pump system PU includes a negative pressure generation mechanism,
It is composed of a valve holder, a cap 104, etc. As can be seen from the relationship with FIG. 2, the ink cartridge 10 is located on the right side of the printer main body 1, and the height direction matches the bottom surface of the main body 1, and is held lower than the inkjet head head IJU. head head I
Keep the tip of the JU under negative pressure and press the inkjet head IJU.
This prevents ink from dripping from the tip.

A lever 10a is rotatably provided on the right side of the printer body 1 by means of a fulcrum tab fixed to the printer body 1. As shown in FIG. By operating this lever 10a, the ink cartridge 10 can be attached or detached (replaced). A switch SW2 for detecting the presence or absence of the ink cartridge 10 is disposed behind the ink cartridge 10.

Incidentally, an electric circuit CIR is provided at the upper part of the ink cartridge 10, which is fixed to the printer main body 1 by a known method. This electric circuit CIR includes the printer body 1
The input terminal IN exposed on the rear right side of the is connected.

Further, an electronic mPS is disposed on the rear left side of the printer main body l.

By arranging the electrical system as described above, it is possible to economize on board removal, and furthermore, the heat generated by the circuit is reduced by the ink cartridge 10,
The influence on the inkjet head IJU is minimized. Furthermore, since the mechanical system and the electrical system are arranged separately, assembly and maintenance are facilitated.

Here, the above-described attachment/detachment knob 5 of the cassette 2 is formed in an abbreviated shape and is attached with a portion thereof exposed on the front surface of the printer main body 1.

This knob 5 is biased inward by a spring 13 and configured to be able to slide in the direction of the arrow by means of a guide pin (not shown) or the like. Furthermore, cassette 2
A pin 5a is implanted upward at the distal end extending to the lower center of the holder. On the other hand, a triangular-shaped cam 2a is fixed to the center of the lower surface of the cassette 2 so as to be locked by a pin 5a. This cam 2a is
Cassette 2 along with pin 5a! It constitutes an ivy mechanism. In addition, the two-dot chain line in the figure shows the state in which a large-sized cassette is installed.

Cassette> Next, the configuration of the cassette 2 that accommodates the MP for printing will be described with reference to FIGS. 4 to 8.

FIG. 4 is a partially cutaway perspective view of the small-sized cassette 2. FIG. The cassette 2 includes a cassette-like cassette body 2' with an open top. As shown in FIGS. 3 and 8, the lower surface of the cassette body 2' is provided with the aforementioned cassette locking cam 2a. Furthermore, as shown in FIG.
A receiving part 2b is provided for receiving the spring 31 attached via the receiving part 2b.

In this way, the cassette 2 is always subjected to a biasing force by the spring 31 so as to be taken out in the removal direction. Therefore, when the locking cam 2a and the bin 5a are disengaged and the lock is released, the cassette 2 is automatically taken out forward by the biasing force of the spring 31.

Further, as shown in FIG. 8, two holes 2h are formed in the rear part of the cassette main body 2' in a row in the vertical direction. A bottle 2c is selectively arranged in each hole 2h. Here, the protrusion 35 provided protrudingly from the bottom of the printer main body 1 is formed with a protrusion that fits into the hole 2h formed in the cassette main body 2', and the end face of each protrusion is A recess into which the bottle 2c is inserted is formed. Switches SW4 and SW5 operated by the bottle 2c are provided in the two recesses, respectively.

Here, in the small cassette 2, the bottle 2c is located in the upper hole 2h.
On the other hand, in the large cassette, the bin 2c exists only in the lower hole 2h and selectively operates the switch SW5. This allows the size of the cassette to be determined.

This single fruit M (M only describes two types of cassettes in detail, but it is not limited to these and can be distinguished from any number of types. Also, the bottle 2C inserted into the hole 2h is a cassette. This is to prevent the bin 2C from folding or getting your hands dirty when removing the bin 2C from the printer body 1 and inserting the paper P, and also to prevent jams, etc.
When you pull out the cassette 2 and pull out the paper from the platen 22, you may accidentally set SW4. In order to operate SW5 and prevent it from malfunctioning, both switches SW4. SW
5 is fixedly installed in a place where fingers cannot reach.

As shown in FIG. 4 again, the front part of the cassette body 2'
A paper front presser 2d is integrally formed at the center of the paper P in the width direction. The front presser foot 2d has a triangular cross section, the lower surface is approximately horizontal, and the slope is
It is designed to rise towards the front. By configuring the front presser 2d in this way, the front presser 2d
After the paper P that was being held down is pulled back,
Even if the paper P is fed forward, the paper P is
It is designed so that it can be lifted upward along the slope without getting caught.

The reason why the front presser 2d is located only at the center in the width direction of the paper P is because it has the following advantages compared to having the front presser 2d at the front or both ends.

1. The load during separation is small.

2. When separating, the two paper feed rollers 18 and this front presser 2d
These three points ensure the flatness of the paper, so the paper P can be stably separated.

3. When feeding paper toward the platen roller 22, the front presser foot 2d is located at the center and locally, so even if the paper is curled, the probability of it being caught is extremely low.

Although the front presser 2d has been described as being formed integrally with the cassette main body 2', the present invention is not limited thereto. It may be configured so that they abut, or it may be configured so that it is swingably attached.

Furthermore, an intermediate plate 14 is housed within the cassette body 2' so as to be movable in the vertical direction. A guide 2e in the front and back direction of the middle plate 14 is formed on the front side of the cassette body 2', and a guide protrusion 14e formed on the front side edge of the middle plate 14 is inserted into both guides 2e. - Guided. Furthermore, side guides 2f for paper P are provided on both front sides of the car set main body 2'. Further, upper restricting portions 2g of the middle plate 14 are formed on both rear sides of the cassette body 2'. This restricting portion 2g is for pressing down a convex portion 14f formed at the rear side edge of the middle plate 14.

In this cassette body 2', the regulating part 2g and the front □
The presser foot 2d restricts upward movement of the middle plate 14. The guides 2e, the side guides 2f, and the restricting portions 2g are each integrally fixed to the cassette body 2'.

The aforementioned middle plate 14 has a slope 14a provided in the front half and slopes downward toward the front, and a convex portion 1 provided in the center.
4b, a friction material 14c attached on a horizontal surface provided in the rear half, a soft sheet 14g placed on the convex portion 14b, and a guide that engages with the guide 2e and side guide 2g of the cassette body 2', respectively. It is comprised of portions 14e and 14f, and a contact portion 14d with a separation lever 15, which will be described later. This middle plate 14 has coil springs 33 at both its front and rear parts.
a and 33b bias upward.

The separation lever 15 is formed into a substantially U-shape, and the base end of the separation lever 15 extends along the rear edge of the cassette body 2', and both ends extend along the side edges of the cassette body 2'. It extends to near the center. Cam portions 15b are provided at both ends.
, 15c are attached respectively. Further, the separation lever 15 is rotatably supported around a fulcrum 15a provided near the center of the cassette body 2' in the longitudinal direction.

Note that this separation lever 15 does not need to be rotatably supported on the shaft, and may be configured to be swingably attached to the cassette body 2', for example. It suffices if it is configured to be supported movably.

Furthermore, a separation portion 15d is provided near the center of the base end of the separation lever 15. Note that a separation plate 16 is fixed to the base end of the separation lever 15 where the separation portion 15d is provided. This separating plate 16 includes a separating part 16a having a convex part that is constricted and protrudes downward, and a paper regulating part 1.
6b.

Here, the reason why the separating portion 16a of the separating plate 16 is made convex downward as shown in FIG. 7A is to reduce the contact resistance with the paper and to prevent the paper from curling. That is, if the separation part 16a is formed into a flat plate shape as shown in FIG. 7B, the paper will not enter the separation part due to the influence of both ends of the flat plate due to curling of the paper, but if it is squeezed, the paper will not enter the separation part as shown in FIG. As shown, the paper easily passes through the gap defined between the heel portions 15d and 16a and is separated. The size t of the gap between the separating portions 15d and 16a is set to the relationship t + < t < 2 t 2 , where the thickness t1 of nine sheets of paper P is assumed.

Furthermore, as shown in FIG. 6A, this separating portion 16a is inclined by an angle θ with respect to the direction in which the paper moves backward. That is, as shown in FIG. 6B, even when the paper is curled downward, it is not affected by the problems caused by this curl. In this way, no matter what kind of curl the paper has, the paper will smoothly move into the gap t using the slope of the separation part 16a as a guide.

The friction material 14c of the middle plate 14 may be provided for feeding the final paper in the cassette main body 2', and may be provided by a known separation method (
Ex, Zheng Fang Zhao) has the same effect. This a! The friction material 14c is set to have a coefficient of friction that is approximately the same as but higher than that of paper, and is made of suede, cork, etc., for example.

Further, the sheet 14g of the intermediate plate 14 is provided to protect the printed portion of the paper. That is, as shown in FIG. 5, the paper P is inserted into the cassette main body 2' with the print side facing downward, and therefore, the last paper, that is, the bottom paper is always convex. The portion 14b receives a concentrated bending load,
This results in local deformation. Such local deformation may cause slight differences in color development, scratches, etc., locally after printing. In order to prevent this, 14g of cloth (for example, cloth such as suede) is adhered to disperse the load instead of localizing it.

Here, if the convex portion 14b of the middle plate 14 is provided over the entire width, when the paper is pushed down by the two pairs of paper feed rollers 18, if the paper is curled, the paper may be thick. The effect of providing this convex portion 14b is lost. Therefore, by providing a local convex portion 14b in the center and pushing it down with a pair of paper feed rollers 18, a vertical curl is forcibly formed and the rigidity of the vertical curl is utilized.
The leading edge of the paper can be effectively lifted.

This has been confirmed through experiments.

Further, as shown in FIG. 5, the aforementioned cam portions 15b and 15c are activated when the separation lever 15 is rotated when loading the paper P.

The middle plate 14 in contact with the coil spring 33a is connected to the coil spring 33a.

It is formed in such a shape that it is pushed down against the urging force of 33b. In this way, when loading the paper P, the cam portion 1
5b and 15c push down the middle plate 14, so that the leading edge of the middle plate 14 is largely separated downward from the front presser 2d of the cassette body 2', as shown in the figure. As a result, the leading end of the stack of sheets P to be loaded will fit well between the front presser 2d and the leading edge of the middle plate 14.

In addition, when the separation lever 15 is rotated back to its original position with the bundle of papers P loaded on the middle plate 14, the cam portion 15b of the separation lever 15 is removed.

15c no longer presses the middle plate 14, and therefore the middle plate 1
4 is lifted by the urging force of the coil springs 33a and 33b. In this way, the leading end of the bundle of papers P is elastically pressed from below against the lower surface of the front presser 2d by the middle plate 14.

For large-sized cassettes, the separating parts 15d, 1
5e, it can be considered that the separation plate 16 is lowered to the rear and the width is expanded, and since the separation plate 16 is substantially the same, detailed explanation will be omitted. However, as is clear from FIG. 3, the U-shaped separation levers 15 have the same width, and the cassette width dimensions are also set to be the same.

Cassette Mounting Section> As described above with reference to FIGS. 2, 3, and 8, the printer main body 1 has an attachment/detachment knob 5 that locks the cassette 2 in the installed state, and It has a spring 31 that biases it.

Further, as shown in FIG. 8, for positioning the cassette 2, the above-mentioned protrusion 35 is provided in the front-rear direction of the cassette 2, and a guide 17 is provided in the up-down direction. When the cassette 2 is mounted, the guide 17 engages with a convex portion 15c formed on the separation lever 15 to forcibly rotate the separation lever 15 downward. In this way, as the cassette 2 is installed, a bending load is forcibly applied to the paper P loaded in the cassette 2 using the front presser 2d of the cassette body 2' and the convex portion 14b of the middle plate 14 as fulcrums. Accordingly, the purpose is to give the paper a horizontal curl once and then correct the vertical curl (that is, the paper normally has a vertical grain, that is, a vertical curl with respect to the feeding direction).

Incidentally, the cassette 2 installed in the printer main body 1 in this way
To take out the cassette 2, the attachment/detachment knob 5 is slid laterally to release the lock, and the cassette 2 is ejected to the outside by the biasing force of the spring 31. Here, at the time of taking out, the cam portions 15b, 15 of the separation lever 15
The guide 17 comes into contact with c, and the printer body 1
Removal of the cassette 2 is stopped at an appropriate position where the cassette 2 is more partially protruded, thereby preventing accidents such as the cassette 2 falling from the printer main body 1.

Paper Feed System PF> Next, the paper feed system PF will be described with reference to FIGS. 8 and 9.

The paper feed system PF includes a paper feed roller 18 that engages with and feeds the uppermost sheet of the loaded paper P. The paper feed roller 18 is formed into a half-moon roller shape to facilitate attachment and detachment of the cassette 2, and has a plurality of roller bodies 1 disposed apart from each other along the axial direction.
8a, a shaft 18c to which these roller bodies 18a are coaxially fixed, a pulley 18d coaxially fixed to one end on the front side of this @18c, and a pin 18f fixed coaxially adjacent to this pulley 18d, The gear 18e is integrally formed with the gear 18e.

Note that both edge portions of the paper feed roller 18 are provided with cam portions tab made of resin with relatively low frictional force. Furthermore, rubber serving as a high friction material is adhered to the circumferential surface of the roller body 18a.

The shaft 18c described above is rotatably installed on a base plate (not shown) of the printer main body 1 via a bearing or the like on a base plate (not shown), and is connected to a pulse motor M2 as a paper feeding motor. Further, the pulley 18d is connected via a belt 36 to a pulley 25 having a pin 25a on the outer periphery so as to rotate at a ratio of 1:1. This pulley 25 is rotatably supported on a ground (not shown) so as to be located adjacent to and above a platen roller 22, which will be described later.

Note that the bin 25a is adapted to engage with a cam portion 27b of a movable paper guide 27, which will be described later.

A switch SW6 is disposed outside the gear 18e. This switch SW6 is configured to be operated by a pin 18f of the gear 18e, and thereby functions as a switch for detecting the initial position of the paper feed roller 18.

Further, as shown in FIG. 8, paper guides 19 and 20 are fixedly installed within the printer body 1. One paper guide 1
9 is disposed with a tip extending below the platen roller 22, which will be described later, and the fed paper contacts the outer periphery of the platen roller 22, which is made of rubber. This is provided in order to prevent the roller from reaching the rolling contact portion with the registration roller 21, which serves as an idle ruler and is in rolling contact with the registration roller 21 for preventing paper from skewing.

That is, the paper guide 19 includes a flat portion 19a that extends along a substantially horizontal direction and is located forward of the tip end. This flat portion 19a functions to press down the paper P from above so that a loop of the paper P that occurs when the paper P is fed, which will be described later, does not become too large. With this configuration, one of the problems is that when the leading edge of the paper hits the rolling contact portion between the registration roller 21 and the platen roller 22 and the loop is further formed too large, the leading edge part Pf of the paper can be reversed. This is effective in preventing the registration roller 21 and the platen roller 22 from returning to the contact area and separating from the contact area. Another reason is that by pressing down on the formation of the loop from above, the spring force of the paper is reduced. In order to generate a conveying force (thrust force), especially in order to secure a wide printing range as in this embodiment,
Even when the registration roller 21 is located on the back side, this is effective in ensuring that the paper leading edge Pf reaches the rolling contact portion of both rollers 21 and 22.

A platen roller 22 is provided to further convey the paper fed by the paper feed roller 18 to the printing section.

This platen roller 22 is constructed by press-fitting a rubber roller onto a shaft 22a. The registration roller 21 described above is arranged so as to be in pressure contact with the outer peripheral surface of the lower half of the platen roller 22 on the back side, and the pinch roller 23 is placed on the outer peripheral surface of the upper half of the platen roller 22 on the back side.
are arranged so that they come into contact with each other. Note that both the registration rollers 21 and the pinch roller 23 are biased so as to come into pressure contact with the platen roller 22 by a spring (not shown).

As the platen roller 22 rotates, the paper P is fed while being held between the registration roller 21, the pinch roller 23, and the platen roller 22. Here, the distance between both the registration rollers 21 and the pinch roller 23 determines the effective printing range, in other words, the printing range. That is, good printing results cannot be obtained unless the top edge of the paper is engaged with the upper pinch roller 23, and good printing results are not obtained unless the bottom edge of the paper is engaged with the lower registration roller 21. You won't get it.

For this reason, both registration rollers 21 and pinch roller 23
The distance between the inkjet head and the inkjet head is set to be as narrow as possible without interfering with the printing operation by the inkjet head IJU. In other words, as described above, in order to ensure a wide printing range, the lower registration rollers 21 are arranged as far away as possible.

On the central outer circumferential surface of the platen roller 22 mentioned above, namely,
An annular recess is formed in the center of the paper in the width direction.
A paper sensor 24 that detects whether or not the paper P is wrapped around the platen roller 22 is disposed within this recess. This paper sensor 24 is a reflective photosensor, and is fixed to a guide plate 26 (described later) so as to maintain an immovable position even when the platen roller 22 rotates.

Note that the paper sensor 24 is positioned so as to detect the leading edge of the paper slightly protruding upward from the registration roller 21. Note that this paper sensor 24 is not limited to a reflective type photosensor, but may be a transmission type photosensor, or may be a mechanical switch such as a proximity switch or a limit switch. is paper P
Anything is fine as long as the tip can be detected.

The guide plate 26 described above is fixed to a base plate (not shown) of the printer main body 1. This guide plate 26 is located above the paper feed roller 18, and guides the stacker section 26a, which temporarily stacks the ejected paper, and a pair of paper ejection rollers 28 and 29, which will be described later, to transport the paper that has completed the printing operation. Paper guide section 2
6b and the mounting section 26 for attaching the paper sensor 24.
It has c.

In addition, the lower registration roller 21 and platen roller 22
A leaf spring 34 for holding the paper is disposed so as to come into contact with the outer circumferential surface between the paper. This leaf spring 34 ensures that the paper that has passed through the lower registration roller 21 does not separate from the outer peripheral surface of the platen roller 22 and is securely connected to the platen roller 22 and the inkjet head. It will be brought between Jυ.

Further, a movable paper guide 27 is provided to guide the paper so that it is smoothly conveyed on the outer peripheral surface of the platen roller 22 between the inkjet head IJU and the upper pinch roller 23. The movable paper guide 27 is rotatably supported around the same axis as the shaft 22a of the platen roller 22, is urged counterclockwise by a spring 37 as shown by arrow A, and is fixed to the printer body 1. The position is regulated by a paper guide 30 provided. This spring 37
Originally, even without this, the movable paper guide 27 would be driven by the action of the cam, but by providing this, good reciprocating movement of the movable paper guide 27 without rattling is realized. It turns out.

This movable paper guide 27 further includes the above-mentioned pulley 2.
It has a cam part 27a that comes into contact with the bottle part 25a of No. 5. That is, as the motor M2 rotates, the paper feed roller 18 rotates, and the pulley 25 rotates via the belt 36, and accordingly, the paper guide 27 reciprocates around the platen roller 22 between points C and D. It turns out.

As shown in FIG. 9, this movable paper guide 27 has a window portion 27a formed in the portion where the upper pinch roller 23 is disposed, and the circumferential length of each window portion 27a is as follows. The size is set to allow rotation of this movable paper guide 27. As shown in FIG. 8, when the movable paper guide 27 is at the position indicated by point C, the pin 25a of the pulley 25 is not engaged with the cam portion 27b of the movable paper guide 27, and the biasing force of the spring 37 As a result, the paper guide 30 is brought into contact with the paper guide 30. In this state, the movable paper guide 27 is
It is brought upward to open the gap between the platen roller 22 and the inkjet head IJU.

On the other hand, when the movable paper guide 27 is in the position indicated by the dot in FIG.
5a is engaged and is in a state where it can rotate in response to the rotation of the pulley 25 against the biasing force of the spring 37. In this state, the movable paper guide 27 is brought downward,
The space between the platen roller 22 and the inkjet head IJU is closed.

As shown in FIG. 9, a gear 38 is coaxially attached to one end of the shaft 22a of the platen roller 22 on the near side. This gear 38 is a pulse motor Ml (paper feed motor)
The driving force of cam 39. It is connected to the shaft 22a of the platen roller 22 via a known one-way latch CL constituted by a pin 40 and a spring 41, and is connected to the shaft 22a of the platen roller 22.
The platen roller 22 is configured to transmit only a driving force in one direction to the platen roller 22. Therefore, the rotation direction of the platen roller 22 is only the direction shown by arrow A in FIG.

Furthermore, the paper discharge rollers 28 and 29 are disposed such that their rolling contact portions are located in the conveyance path of the paper P guided by the paper guide portion 26b of the guide plate 26. The upper paper ejection roller 29 is made of a roller made of plastic or the like, and is designed not to adversely affect the printed portion of the printed paper, and is integrally formed with a shaft 29a, as shown in FIG. It is rotatably supported by a bearing 47 of the printer main body 1. On the other hand, the lower paper ejection roller 28 is formed from a rubber roller, and is press-fitted onto the shaft 28a. A gear 44 is integrally attached to one end of this shaft 28a, and is configured to rotate together with the gear 44.

On the other hand, the base plate 42 is arranged so as to rotatably support @l128a at the tip. The base plate 42 is rotatably attached to a shaft 42a at its base end, and the shaft 42a is rotatably supported by a bearing (not shown). Therefore, the base plate 42 swings and rotates around the shaft 42a.

A gear 43 rotatably driven by a pulse motor M1 is rotatably fitted to this shaft 42a, and the gear 43 meshes with a gear 44 located at the tip of the base plate 42. This gear 44 is integrally fixed to a shaft 28a to which a lower paper ejection roller 28 is coaxially fixed, and the shaft 28a rotatably passes through the tip of the base plate 42. This base plate 4
2 and the gear 44 are connected to each other by a friction transmission mechanism composed of a spring 45 and a friction plate 46 that is pressed against the tip of the base plate 42 by the biasing force of the spring. That is,
The friction torque determined by the biasing force of the spring 45 and the friction coefficients of the friction plate 46 and the base plate 42 is T I s.If the load torque is T2, then when TI > 72, the gear 44 is moved to the base plate by the friction torque T1 of the friction transmission mechanism. 42 in a non-rotatable manner.

Therefore, the gear 44 is rotated in accordance with the rotation of the gear 43.
It will revolve around 3. In this way, the main plate 42 rotates around @42a in the clockwise direction indicated by arrow A.
The lower paper ejection roller 28 is separated from the upper paper ejection roller 29.

Note that T I < T 2 because the base plate 42 that has rotated downward comes into contact with a stopper (not shown). In this case, the gear 44 rotates in response to the rotation of the gear 43 against the friction torque T1. In this way, the lower paper ejection roller 28 is driven to rotate in the clockwise direction indicated by arrow A, but since the lower paper ejection roller 28 has already separated from the upper paper ejection roller 29, The paper ejecting operation is substantially stopped.

On the other hand, when the lower paper ejection roller 28 is separated from the upper paper ejection roller 29, the pulse motor M1 reverses and starts rotating counterclockwise as shown by arrow B. 72, the base plate 42 rotates counterclockwise around the shaft 42a, and the lower paper ejection roller 28 rotates in the upper paper ejection roller 2.
9. As a result, TI <”r.

As gear 43 rotates counterclockwise, gear 44 rotates.
will be rotated clockwise.

According to the rotation of this gear 44, both phase paper rollers 28 and 29
The two rotate in a state where they are in contact with each other. In this way, the paper ejecting operation is executed.

At this time, the rotational directions of the gear 38 and the gear 44 are connected in a relationship as indicated by the arrows also shown in FIG.

That is, the pulse motor M1 rotates in one direction, the gear 38 rotates in the direction shown by arrow A, and the platen roller 22 is similarly driven in the direction shown by arrow A via the one-way clutch CL. swings in the direction indicated by arrow A, and the two phase paper rollers 28, 29 are separated from each other as described above.

In this way, the ground plate 42 hits a stopper (not shown) and the load increases, causing the gear 44 to rotate in the direction indicated by arrow A. That is, the platen roller 22 always rotates while bearing the friction torque T. Due to this friction torque TI, the platen roller 22 when the motor M1 is intermittently fed
It is possible to prevent vibrations, etc., and improve paper feeding accuracy.

Here, when the pulse motor M1 reversely rotates in a direction opposite to the one direction described above, the gear 38 rotates in the direction shown by arrow B, but the one-way clutch CL causes the platen roller 2 to
The rotation is not transmitted to platen roller 22, and platen roller 22 remains stationary. Further, the base plate 42 swings in the direction shown by arrow B, the two phase paper rollers 28 and 29 come into contact with each other, the gear 44 rotates in the direction shown by arrow B, and the paper discharge roller 28 discards the paper P. Rotate in the direction. That is, the paper P held between the double-sided paper rollers 28 and 29 is ejected.

This one-way clutch CL prevents the paper P from being reversely inserted into the platen roller 22 even when the paper P is caught in the middle, and also removes the load on the rotation system of the platen roller 22 when discharging the paper, thereby reducing the The only driving force is Therefore, stability during paper ejection is improved, and paper can be stably ejected even in various harsh environments. Note that the discharged paper P is stacked on the stacker section 26a and can be taken out from the paper discharge port 11.

To summarize the configuration of the paper feed/delivery system so far, the paper feed roller 18 rotates in the direction shown by arrow B due to the rotation of the pulse motor (paper feed motor) M2 in the opposite direction, and the paper P is fed backwards. It enters the gap (1) between the separation parts 15d and 16a and is separated.

Next, the pulse motor M2 reverses and rotates in the normal direction, so that the paper feed roller 18 rotates in the direction shown by arrow A, and the paper P is sent toward the platen roller 22.

At this time, the leading edge of the paper is lifted up by the guide convex portion 14e of the intermediate plate 14 and is conveyed toward the platen roller 22 without hitting the presser portion 2d.

Then, the taken out paper P is conveyed via the paper guides 19, 20 to the rolling contact portion between the platen roller 22 and the lower registration roller 21. Since the rotation of the platen roller 22 is stopped in this state, the skew of the paper is corrected at this rolling contact portion. At this time, the second and subsequent sheets of paper P are pressed by the front presser 2d.
Since the paper is held down by the machine, double feeding will not occur.

Next, the pulse motor M1 rotates in one direction and the platen roller 22 is slightly rotated in the direction indicated by arrow A, thereby inserting the paper P between the platen roller 22 and the registration roller 21 and stopping.

Next, the pulse motor M2 rotates, and the pulley 25 rotates to move the movable paper guide 27 to point D. Furthermore, the pulse motor M1 rotates to rotate the platen roller 22 in the direction shown by arrow A, thereby causing the presser spring 34 and the movable paper guide 2 to rotate.
The paper P is sent through a paper guide section made of 7 and the leading end of the paper P is inserted between the upper pinch roller 23 and the platen roller.

Next, the pulse motor M2 rotates to return the paper feed roller 18 to the initial position (the position shown by the solid line in FIG. 8) and return the movable paper guide 27 to the zero point, making printing possible. Next, the pulse motor M1 is rotated to feed the paper P, and when the rear end of the paper P is removed from the pressure contact point between the platen roller 22 and the pinch roller 23, the pulse motor M2 is reversed and the paper discharge roller 28 is moved to the dotted line position. The sheets are moved from the position shown in the solid line (FIG. 8) so that they roll into contact with each other, and are further rotated in the direction shown by arrow B to eject the paper.

The detailed operation in this embodiment will be described later.

Note that the above-described movement of the lower paper ejection roller 28 toward and away from the upper paper ejection roller 29 does not have to be achieved by planetary motion of the gear 44 using such friction; A configuration using a cam mechanism may also be used.

11 shows a block configuration diagram of the control section of the embodiment device. In the figure, this control unit is a central processing unit (CPU) that handles the main control of the printer device.
)9 t i.

The CPU 911 stores control programs shown in FIGS. 12A and 21H, for example, in a ROM (not shown), and controls the following peripheral circuits by executing this program.

A signal input section 901 is connected to this CPU 911, and via this signal input section 901, an RGB color image signal, a color television signal of NTSC, PAL, or SECAM system, or a signal formed by a personal computer, etc. Various color image signals are input. The CPU 911 also includes an input signal processing circuit 902 that converts color image signals other than RGB into RGB signals, and a line memory 9 that stores color image data for multiple lines.
04. Interpolation circuit 905 when enlarging a color image;
An image processing circuit 906 that performs color image data masking processing, undercolor removal processing, etc., and an inkjet head IJ.
U driver circuits 908 are connected to each other.

Note that the above-mentioned line memory 904 stores analog RGB image signals from the input signal processing circuit 902 as digital RG signals.
An A/D converter 903 for converting into B image data is connected to the head driver 908, and an A/D converter 903 for converting color image data from an image processing circuit 906 into an analog image signal is connected to the head driver 908.
A converter 907 is connected. Further, the head driver 908 is a piezo type inkjet head IJ.
Connected to LI.

Furthermore, the CPU 9tt has various operation switch groups 910.
is connected. This operation switch group 901 includes the aforementioned power switch 6, print switch 8, pump switch, and the like. Furthermore, the CPU 911 has
Pump system sensor 913, ink temperature sensor 917, encoder sensor 920, carriage motor driver circuit 921, motor M1 driver circuit 923, motor M
The driver circuit 925 of No. 2 and the driver circuit 927 of the LED display group 928 are connected.

Note that the LED display group 928 includes display LEDs 7a to 7.
e is included.

The operation will be explained below.

<Cassette operation> When the knob 5 for attaching and detaching the cassette shown in FIG. 3 is moved to the left against the biasing force of the spring 13, the bin 5a fixed to the knob 5
The cam part 2a on the bottom surface of the cassette 2 is unlocked, and the cassette 2 is pushed out from the printer main body 1 by the bias of the return spring 31 shown in FIG. It stops at the point of contact. As a result, both cassette size sensors SW4 and SW5 are turned off, and by further pulling out the cassette 2 by hand, the cam portion 15c climbs over the lower surface of the guide 17, allowing the entire cassette 2 to be pulled out.

In FIG. 5, when the separation lever 15 is rotated in the direction shown by arrow A around the fulcrum 15a of the separation lever 15, the cam portions 15b and 15c come into contact with the contact portion 14d of the middle plate 14 in FIG. 14 is pushed down as shown in FIG. 5, especially the leading edge of the paper P placed on the middle plate 14 is lowered, and the gap between it and the front presser foot 2d becomes larger. As a result, the separation lever 15
Even if the operator takes his hand off, it maintains its position due to its own weight and the action of the cam, allowing the operator to load the paper P along the direction B indicated by the arrow with both hands. When the separation lever 15 is returned to its original position after loading the paper,
The middle plate 14 is pushed up by the biasing force of the coil springs 33a and 33b until the top of the leading edge of the paper comes into contact with the front presser foot 2d.

Next, as shown in FIG. 2, the cassette 2 is inserted into the paper feed port 11 of the printer main body 1. As a result, the separation lever 15
The cam portion 15c is pushed down midway by the guide 17 shown in FIG. 8, thereby pushing down the separation plate 16 attached to the separation lever 15. As a result, the trailing edge of the paper is pushed down, and the vertical curl of the paper is corrected by being bent by the convex portion 1.4b. Furthermore, the cassette 2 is attached to the spring 31.
When the cam portion 15b is pushed in against the urging force of the cam portion 15b.

15c climbs over the guide 17, and the cam portion 2a of the cassette 2 shown in FIG. 3 pushes away the pin 5a, and locks at the point where it gets over this cam portion 2a. In this state, the printer body 1
The protrusion 35 positions the tip of the cassette 2 as shown in FIG. 8, and SW4 is selectively turned on when the cassette is a small cassette, and SW5 is selectively turned on when the cassette is a large cassette. In this way, the cassette 2 can be easily and reliably set in the printer main body 1.

After loading, the paper P is pressed in front of the paper P by the cassette spring 33a via the middle plate 14 against the front presser 2d with an appropriate pressure as described later. Also, at the rear, the front presser foot 2d mentioned above
Since there is no fixed object such as a fixed object and the separation lever unit consisting of the separation lever 15 and separation plate 16 is rotatable, the upward rotation of the separation lever 15 is restricted by the guide 1f, and the separation lever 15 is fixed to the separation lever 15. The paper P is pressed against the provided separation plate 16 via the middle plate 14 by the rear cassette spring 33b.

In this way, when the cassette 2 is installed in the printer main body 1, the front and rear ends of the top paper P are both pressed against the front presser 2d and the separation plate 16 by the spring force pushing up from below, so the number of sheets loaded changes. However, the top paper always maintains a constant height with respect to the paper feed roller 18.

12A to 12H show flowcharts of various control programs executed by the CPU 911.

Initial Process> FIG. 12A shows a flowchart of the initial process from power-on of the printer device to standby state. In step 5tot, the operator presses the power switch 6. Process 5
In step 102, the current state of the power switch 6 is checked, and if it is in the ON state, it is turned OFF and the process proceeds to step 5101, where it is turned on.
If it is in the FF state, it is turned on and the process proceeds to step 5103. Note that the above is performed independently by the power supply circuit, and the CPU
This has nothing to do with 911 processing.

Next, conditions necessary for starting printing are inspected and displayed. That is, in step 3103, the loaded state of the cassette 2 is checked, and if there is no cassette 2, an abnormality flag is set in step 5106, and the LED 7a is blinked to notify that there is an abnormality in the paper supply system. In addition, if cassette 2 is loaded, if it is a large size cassette (SW5=ON), the large size is displayed in step 5104, and if the small size cassette (SW4=ON) is loaded, the large size cassette is displayed.
), the normal size is displayed in step 5105. Furthermore, in step 5107, the pinch roller sensor is checked;
If there is an abnormality, an abnormality flag is set in step 5111, and an abnormality in the paper supply system is displayed.

Further, if normal, the ink cartridge sensor SW2 is checked in step 3108, and if the ink cartridge 10 is not loaded, an abnormality flag is set in step 5112, and the ink system abnormality (LED 7b) is blinked. Further, if the ink cartridge 10 is loaded, the presence or absence of an abnormality flag is checked in step 5109, and if there is an abnormality flag, step 511
If it is 0, an abnormality is displayed and the process returns to step 5103. If there is no abnormality flag, normal is displayed in step 5113.

In step 5114, the paper sensor 24 is checked, and if the paper P remains in the paper conveyance path, then in step 5200, a paper ejecting process, which will be described later, is executed. If no paper P remains, the home position sensor SW3 is checked in step 5115, and the carriage 20
1 is not in the home position, a home process to be described later is executed in step 5300.

As a result of the above, if there is no abnormality, the standby state (S
Enter TANDBY). In this standby state, cassette exchange, print commands, and pump commands are received and received. That is, when loading of a new large size cassette is detected in step 5116, the mode is switched to large size mode in step 5130. Also, if loading of a small size cassette is detected in step 3116,
Furthermore, the size switch is checked in step 5117, and if the size switch is set to postcard size, the mode is switched to postcard mode in step 5140, and if it is not postcard size, the mode is switched to normal mode. Also, in step 8118, print switch 8
If the press of the pump switch is detected in step 5119, a print step 5400, which will be described later, is executed, and if the press of the pump switch is detected in step 5119, a pump step 5soo is executed.

Printing Process> FIGS. 12D to 12F show a flowchart of the printing process. The printing process includes a status check process before paper feeding, a paper feeding process, a printing process, and a paper ejecting process.

When the press of the print switch 8 is detected in step 5118, the print LED 8a is turned on in step 5401 to notify that the print operation is in progress.

In step 5600, the next status check step is performed as an inspection immediately before printing starts.

(Status Check Process) FIG. 12H shows a flowchart of the status check process. In step 5601, the dust cover sensor S
Check W1 and confirm that dust cover 4 is closed (SW1=ON)
If there is, LE07a is displayed blinking in step 5602 to notify an abnormality in the paper supply system because it interferes with paper ejection, and the process advances to step 8608 to enter a standby state. The standby state is canceled when the operator opens the dust cover 4. The same applies below. Furthermore, in step 5603, the cassette sensor SW4
Check SW5 and find that no cassette is loaded (SW
4=OFF, 5W5=OFF), in step 5604, the LED 7a is flashed to indicate an abnormality in the paper supply system, and the printer enters a standby state.

Furthermore, in step 5605, the ink cartridge sensor SW
2 is checked, and if the ink cartridge 10 is not loaded (SW2-OFF), the LED 7b is displayed blinking in step 5606 to notify of an abnormality in the ink system, and the printer enters a standby state. Further, if there is no abnormality mentioned above, it is normal and the next paper feeding process is performed.

In the initial process, the OFF state of the paper sensor 24 (Step 5114) and the ON state of the home position sensor SW3 (Step 5115) necessary to start printing have been achieved, but it is necessary to check for this type of abnormality from time to time. Therefore, these inspection steps may be included in the status check step.

(Paper feeding process) FIG. 12B shows a flowchart of the paper feeding process.

The paper feeding process consists of a separation process of separating the uppermost paper PL from the cassette 2, and a conveyance process of sending this separation paper to the platen roller 22.

(1) Separation process In the separation process, only one top paper P1 of the cassette 2 is pulled out in the opposite direction (opposite to the transport direction) and separated. Step 57
01 and step 5702, the paper feed roller 18 is at the initial position α in FIG. 10A. Rotate the pulse motor (paper feed motor) M2 in the opposite direction until (SW6=ON). As a result, the paper feed roller 18, which had rotated slightly in the conveyance direction during the previous paper feed, is moved to the initial position α. Return to

In step 5701, the initial position α is set. , step 570
3, the pulse motor M2 is further rotated by N3 steps in the opposite direction. As a result, first the paper feed (half-moon) roller 1
Cam portion 18b made of resin with relatively low frictional force of No. 8
begins to come into contact with the top paper p. Here, even if the number of stacked sheets changes, the paper feed roller 18 always has a constant height with respect to the top paper P, so the cam portion 1.8b of the rotating paper feed roller 18 moves to the top paper P. , the angle of contact is always constant.

At that time, the frictional force between the top paper P and the second paper 22 is μ
2, the frictional force between the cam portion 18b and the top paper 21 μm
It is set so that there is a relationship of μm × μ2 between. Therefore, when the paper feed roller 18 further rotates, due to the action of the cam portion 18b,
The stacked paper P and the middle plate 14 are pushed down against the coil spring 33b.

As the stacked paper P descends, the separation lever 15 moves toward the guide 1.
7, and the separation plate 16 separates the top paper P only by its own weight accompanied by the moment force of the separation lever 15.

It touches the upper part of the rear end. Further, since the separation lever 15 and the guide 17 have been evacuated, the biasing force of the coil spring 33b becomes a force that exclusively presses the uppermost paper P against the cam portion tab of the paper feed roller 18. In this state, as will be described later, the rubber portion 18a of the paper feed roller 18 has enough pressure to feed the smallest sheet of paper P back and forth.

When the paper feed roller 18 continues to rotate further, the paper feed roller 18
The rubber portion 18a having a relatively large frictional force begins to come into contact with the top paper P. At this time, if the frictional force between the rubber portion 18a and the top paper 21 is μ3, then the relationship between the frictional force μ between the topmost paper P1 and the second sheet 22 is μ2 × μ3. It is set. As a result, the top paper P
, begins to slide rearward (in the direction opposite to the feeding direction) as the rubber portion 18a rotates, and the rear end of the top paper P is fed toward the gap t between the separating portions 15d and 16a.

Incidentally, as shown in FIG. 6A, the separating portion 16a has an angle θ with respect to the traveling direction of the paper P, so that the uppermost paper p+
The rear end portion can always be guided into the gap t along the separating portion 16a.

Furthermore, the separating portion 15d similarly has an angle θ, so that the interval of the gap t is also kept constant.

In this way, while the rear end of the top paper P is guided into the gap t, its front end is pulled out from the front presser 2d, and the tenth
As shown in Figure A, the front half of the top paper P is lifted up by the bending step of the middle plate 14 and the convex part 14b, and the second paper P is lifted up.
Completely separate from 2. At this time, if the pressing force of the coil spring 33a against the paper P against the front presser foot 2d is too small, the paper other than the top paper PI (especially the second sheet) will also be pulled out from the front presser foot 2d; Part 18a
Due to this, the pulling force will be insufficient and separation will not be possible. Therefore, the biasing force of the coil spring 33a is determined by also considering the pressing force of the paper P against the front presser 2d.

Here, the feed amount N and steps of the pulse motor M2 are determined by considering the following points. That is, if the distance m<separation amount) from when the rear end of the uppermost paper P1 passes through the gap t until it hits the abutment part 16b of the separation plate 16 is Sl, then the 10th
There is a relationship of Sl>S2 with the dimension S2 of the front presser foot 2d in Figure A. In this way, when the rear end of the top paper PI is restricted from further rearward conveyance by the abutment part 16b, the carp is assured that the front end of the top paper PI is pulled out from the front presser 2d. ing.

Therefore, the rotation angle α of the paper feed roller 18 in step 5703 is
3, that is, the feed amount N3 steps of pulse motor M2 is
It is determined in consideration of this separation amount SL. Here, as described above, since the angle at which the cam portion 18b of the paper feed roller 18 contacts the uppermost paper P1 is constant, the paper feed amount added at the time of separation may also be constant, so that the pulse motor M2 can fully feed the paper P1. The amount N and steps can also be made constant, resulting in simple control and configuration. Note that the value N3 is set to a large value in consideration of margins under various environments.

(2) Conveyance process In the conveyance process, the separated top paper P is transported in the forward direction (conveyance direction).
send to In steps 5704 and 5705, the paper feed roller 18 is at the initial position α. The pulse motor M2 is rotated in the forward direction (direction A of the paper feed roller 18) until the As a result, the paper feed roller 18 rotates in the forward direction by a rotation angle α and returns to the initial position α.

Returning to
1 to the paper initial position X0 above the front presser foot 2d.

At this point, the rear end of the top paper P has come out from the gap t, so in the next conveyance, the top paper P1
The load passing through the gap and the occurrence of scratches due to contact with the gap can be prevented, and stable conveyance is possible. In particular, when thick paper (for example, thickness of about 0.25□) is used, load fluctuations during printing have a large effect on printing accuracy, so this embodiment, which has no load after separation, is very effective. be.

In step 5704, the initial position α is set. By detecting this, in step 5706, the pulse motor M2 is further rotated by N4 steps in the forward direction. As a result, first the paper feed roller 18
is the initial position α. It rotates in the A direction by a rotation angle α (not shown). Then, the separated top paper P is sent toward the platen roller 22 by the conveyance force of the rubber portion 18a that comes into contact with it. In this way, the front end of the separated paper P is moved along the paper guides 19 and 20 to the platen roller 22.
It comes into contact with the outer peripheral surface of. Then, as the paper feed roller 18 continues to rotate further, a loop-shaped bend occurs in the separation paper below the paper guide 19 as shown in FIG. 10B.

As the paper feed roller 18 continues to rotate further, this loop-shaped bending grows, and this loop forms a flat part 19 of the paper guide 19.
a, a conveyance force is generated on the separation paper due to the spring force caused by the loop, and the leading edge of the paper reliably abuts against the rolling contact portion of the registration roller 21 and the platen roller 22. In this way, the skew of the separation paper is corrected, and the paper feed roller 18 temporarily stops at the angle α3 at this point. In this way, the thrust generated by the spring force of the paper itself ensures that the paper reaches the rolling contact portion between the registration roller 21 and the platen roller 22 even if it is slightly curled.

In step 5707, the pulse motor (paper feed motor) Ml is rotated by xl steps in the transport direction. As a result, the platen roller 22 is slightly rotated in the direction indicated by arrow A in FIG. 10B, and the front end of the paper P is bitten into the rolling contact portion between the platen roller 22 and the registration roller 21.

In steps 5708 and 5709, the paper feed roller 18 is at the initial position α. The pulse motor M2 is rotated in the conveying direction until . This causes the paper feed roller 18 to completely separate from the separation paper P, leaving the latter half of the separation paper P free.

In step 5710, the pulse motor M2 is rotated by N steps in the opposite direction. As a result, the paper feed roller 1 in FIG.
8 is the initial position α. The pulley 18d is rotated by an angle α4 in the direction shown by arrow B from
and a pulley 2 connected one-to-one via a toothed belt 36.
5 is rotated by an angle α4. As a result, the pin 25a integrally formed with the pulley 25 pushes out the cam portion 27b of the movable paper guide 27, and the paper guide 27 resists the biasing force of the return spring 37 and rotates in the direction shown by arrow B in FIG. After the movement begins, the tip of the paper guide 27 has been lowered to the position indicated by the reference numeral to form a guide portion for the separation paper P.

In steps 5711 and 5712, the paper sensor 24 is
The pulse motor M1 is rotated in the conveyance direction until it reaches N. The paper sensor 24 detects the position where the front end of the separation paper P has advanced slightly ahead of the registration rollers 21, and reliably guides the front end of the separation paper P to the paper guide section.

When the ON state of the paper sensor 24 is detected in step 5711,
In step 5713, the pulse motor M1 is further rotated by X2 steps in the transport direction. As a result, the platen roller 22
rotates in the direction shown by arrow A, further conveys the separated paper P via a paper guide section consisting of a presser spring 34 and a movable paper guide 27, and then passes the front end of the paper P between the platen roller 22 and the upper pinch roller 23. Insert it into the transition area with. At this time, since the movable paper guide 27 is formed coaxially with the platen roller 22, this gap can be designed to be small in advance, and the gap between the paper guide portions is always constant.

In this way, when the paper P is bitten between the platen roller 22 and the pinch roller 23, the paper P does not float relative to the platen roller 22. Step 5714 and Step 5
At 715, the paper feed roller 18 is at the initial position α. The pulse motor M2 is rotated in the conveying direction until .

When the initial position of the paper feed roller 18 is detected in step 5714, the pulse motor M2 is further rotated in the forward direction in step 5716.
Rotate by 6 steps. As a result, the paper feed roller 18 further rotates to an angle α4, separating the bin 25a of the pulley 25 and the cam portion 27a of the movable paper guide 27, and the movable paper guide 27 is moved by the biasing force of the spring 37 as shown in FIG. It is retracted in the direction shown by arrow A to the position shown by symbol C, and becomes ready for printing.

(Printing process) Figures 12E and 12F show a flowchart of the printing process. There are roughly three types of print modes; when the paper size is large, the large size mode is uniquely determined, and when the paper size is small, the sub-operation (mode) switch 12a is operated before operating the print switch 8. , you can select normal mode or postcard mode.

In step 5402, the paper sensor 24 is checked, and if the paper is not wrapped around the platen roller 22 in the above-mentioned paper feeding process, the paper sensor 24 is in the OFF state, so the paper feeding has failed.
In step 5403, an LED is turned on to notify of an abnormality in the paper supply system.
7a is illuminated, and in step 5404 it enters a standby state. Further, if paper is wrapped around the platen roller 22, the paper sensor 24 is in the ON state, and therefore paper feeding is normal.

Further, in step 5405, the cassette size is checked, and if the cassette size is large, in step 5407, the pulse motor M1 is moved by X31 steps to form a margin.

Furthermore, in step 8408, "840'' is set in the dot number register in the carriage scanning direction, and in step 5409, 1120" is set in the line number register C in the paper feed direction.If the size is small, the size switch is further set in step 3406. is checked, and if the size is normal, the pulse motor M1 is idle-fed by X32 steps in step 5410.Furthermore,
In step 5411, the dot number register is set to "435", and in step 5412, the line number register C is set to "580".

Also, if it is a postcard size, in step 5413 the pulse motor M
1 by X33 steps, and further, ・Step 541
In step 4, the dot number register L&: ``435'' is set, and in step 5415, the line number register C is set to ``580''. In step 5416, both the dot number counter L1 and the line number counter C1 are initialized to "O", and step 54
At step 17, one line of image data is transferred to the line mesori 904. In step 3418, a linear motor (CR motor) for the carriage (not shown) is driven to start a printing operation.

(1) One-point printing process FIG. 12E shows a flowchart of the one-point printing process. When a change from black (dark) to white (bright) in the zone slit 204b (zone slit 204b' in the case of reverse scanning) is detected in step 5419, it means that the carriage 201 is at the start position of the print zone, and in step 5420
Count the number of dots and set I to "O". Process 5
In 421, if the large size mode is selected, the process directly proceeds to step 5424, and immediately starts detecting the change from black to white in the timing slit 204a. When this change is detected, the dot number counter L! is incremented by 1 in step 5425''. In step 5426, the contents of the dot number counter Ll and the dot number register are compared, and if 1.,<1°, proceed to step 5427. One point is printed, and the next timing slit 204a is detected.

Also, in step 5426, if t, , <L, printing of one line is finished, and the process proceeds to the next line feeding operation.

Note that if it is not the large size mode in step 5421, the process advances to step 5422 or step 5423, and the zone slit 204b (in the case of reverse scanning, the zone slit 204b'
) waits for the detection of a change from white to black. This allows step 5
This is done in order to delay the start of detection of the timing slit 204a of 424 and change the print zone.

(2) Line feeding process Figure 12F shows a flowchart of the line feeding process.

In step 3428, the contents of the line number counter C1 are incremented by 1. In step 5429, the contents of the line number counter C8 and the line number register C are compared, and if C,<C, then in step 5430, a change from white to black in the zone slit 204b' (in the case of reverse scanning, the zone slit 204b) is detected. wait. When this change is detected, the carriage 20
1 means that it is at the end position of the row scan, step 5431
to stop the CR motor.

In step 5432, the number of pulses for one line is applied to the pulse motor M1, and the platen roller 22 is driven in the transport direction to feed the paper by one line.Furthermore, in step 5600, a status check is performed just in case. In step 5433, the next line of image data is transferred to the line memory 904. In step 5434, the drive direction of the CR motor is reversed to perform bidirectional scanning, and the process returns to step 5419. Also, step 5
If C+<C is not found in step 429, printing of one page is completed, and the carriage 201 is returned to the home position in a home step 5300, which will be described later, and the paper is ejected in a paper ejecting step 5200.

(Paper discharge process) FIG. 12C shows a flowchart of the paper ejection process.

In steps 5201 and 5202, the pulse motor M1 is rotated until the output of the paper sensor 24 turns OFF (no paper), and the pulse motor M1 is rotated until the rear end of the paper P wrapped around the platen roller 22 passes the paper sensor 24 section. Transport paper P.

When the output of the paper sensor 24 is turned off, the process proceeds to step 5203, in which the pulse motor M1 is further advanced by x4 steps in the transport direction, and the platen roller 22 is further rotated in the transport direction.

As a result, the rear end portion of the paper P is reliably ejected from between the pinch roller 23 and the platen roller 22. Step 520
4, the pulse motor M1 is rotated in the opposite direction by X steps, thereby rotating the gear 43 in FIG. 9 in the direction indicated by arrow B. As a result, the base plate 42 swings in the direction shown by arrow B, and therefore, the paper discharge roller 28 rotatably placed in contact with the swinging end of the base plate 42 rotates in the direction shown by arrow B. At this time, since the paper P has already been sent between the paper ejection rollers 29 and 28, the paper P is pressed between the paper ejection rollers 28 and 29 by the rotational force of the base plate 42, and due to the rotation of the paper ejection roller 28. will be discharged accordingly.

Although not shown, the paper sensor 2
If the output of the paper sensor 24 is OFF, the rotation control until the output of the paper sensor 24 is turned OFF is omitted, and the pulse motor M1 is immediately rotated by x4 steps in the transport direction. As a result, the base plate 42 swings in the direction shown by arrow A, and the lower paper ejection roller 28 is released downward relative to the upper paper ejection roller 29 and waits below the paper guide 26. In this way, passage of the front end of the paper P is not obstructed. Therefore, the front end of the paper P comes out of the movable paper guide 27, is guided by the paper guides 30 and 26, and is guided between the pair of paper discharge rollers 28, 29.

Margins below [Effects of the Invention] As detailed above, the recording device according to the present invention includes a platen roller that is rotatably provided around a predetermined rotation axis, and a platen roller that is located on the outer periphery of the platen roller. A paper guide member that is rotatably provided around the same axis as the rotation axis and guides the paper to be printed on the outer peripheral surface of the platen roller, and a first guide member that guides the paper to the printing position. It is characterized by a driving means that rotates back and forth between the first position and a second position for guiding the paper during printing.

Therefore, according to the present invention, it is possible to reliably guide the paper to the printing position without separating it from the pinch roller and the rough latin roller, and it is also possible to guide the paper so that the paper after printing is reliably removed from the printing position. Thus, a recording device is provided which can perform the above-mentioned functions and has a simple structure of the guiding mechanism.

Margin below

[Brief explanation of the drawing]

Fig. 1 is a perspective view showing the external appearance of the printer device, Fig. 2 is a perspective view showing the printer device shown in Fig. 1 with the decorative lid and dust cover open, and Fig. 3 shows the internal configuration of the printer device. Figure 4 is a schematic top view, Figure 4 is a partially cutaway perspective view of the structure of the cassette, and Figure 5 shows the state of the cassette in which a bundle of paper can be loaded by rotating the separation lever. Figure 6A is a side sectional view showing how the separation section and separation plate are installed, and Figure 6B is a schematic view of the conventional state in which paper curled downward is not separated along the horizontal separation plate. 7A and 7B are front views showing the shape of the separation plate and modifications thereof, respectively. FIG. 8 is a side sectional view showing the structure inside the printer main body in which the cassette is inserted. Figure 10A is a perspective view showing the structure of the paper supply system, Figure 10A is a side sectional view showing how the paper is separated by the paper feed roller, and Figure 10B is the separated paper up to the rolling contact between the platen roller and registration roller. 10C is a side sectional view showing the conventional positional relationship between the paper feed roller, platen roller, registration roller, and pinch roller, and FIG. 11 shows the cPU and each device in the control system of the printer device. , a block diagram showing the connection relationship with the equipment, FIG. 12A is a flowchart of the initial process from power-on to standby state, FIG. 12B is a flowchart of the paper feeding process, FIG. 12C is a flowchart of the paper ejection process, and FIG. 12D 12F to 12F are flowcharts of the printing process, FIG. 12G is a flowchart of interrupt operation when the power is turned off, and FIG. 12H is a flowchart of the status check process. In the figure, 1... printer main body, 2... cassette, 2'
...Cassette body, 2a...cam, 2b...receiver, 2C...pin, 2d...front presser, 2e...
Guide, 2f side guide, 2g...regulating section, 2h...
... Hole, 21... Decorative lid, 3a... Nail, 4...
Dust cover, 4a...claw, 5...removal knob,
5a...Pin, 6...Power switch, 7...Display unit, 78-7C...Display section, 7f...Dust cover, 8...Print switch (main operation switch), 8a
...LED, 9...Main operation switch, 10...Ink cartridge, 10a...Lever, 10b...
Fulcrum, 11...Paper feed port, 12...Sub-operation system switch, 13...Spring, 14...Medium plate, 14a...Slope, 14b...Protrusion, 14c...Friction Body, 14d...
・Contact part, 14e; 14f... Guide convex part, 14g
... Soft sheet, 15 ... Separation lever, 15
a...Fully point, 15b; 15c...Cam part, 15d...Separation part, 16...Separation plate, 16a.
...Separation section, 16b...Paper regulation section, 17...Guide, 18...Paper feed roller, 18a...Roller body, 1
8b...Cam part, 18c...Shaft, 18d...Pulley, 18e...Gear, 18f...Pin, 19...
Paper guide, 19a... Planar part, 20... Paper guide,
21... Registration roller, 22... Platen roller, 22a... Shaft, 23... Pinch roller, 24...
・Paper sensor, 25...Pulley, 25a...Pin, 2
6... Guide plate, 26a... Stacker section, 26b.
...paper guide section, 26c...mounting section, 27...movable paper guide, 27a...window section, 27b...cam section, 28...lower paper ejection roller, 29...・Upper paper discharge roller, 30...Paper guide, 31...Spring, 32 Mounting part, 33a; 33b...Coil spring, 34...
- Leaf spring, 35... Protrusion, 36... Belt, 37
...Spring, 38...Gear, 39...Cam, 40...
...Pin, 41...Spring, 42...Main plate, 42a...
...shaft, 43...gear, 44...gear, 45...
Spring, 46...Friction plate, 47...Bearing, SWl...
・Dust cover switch, SW2... Ink cartridge switch, SW3... Home position sensor,
SW4: Small cassette detection switch, SW5: Large cassette detection switch, SW6: Paper feed roller initial position detection switch. Patent applicant Yasunori Otsuka, patent attorney for Canon Co., Ltd.; 2.゛12th month

Claims (4)

[Claims] (1) A platen roller that is rotatably provided around a predetermined rotation axis; A platen roller that is located on the outer periphery of this platen roller and that is rotatable about the same axis as the platen roller's rotation axis, and that holds the paper to be printed on the platen roller. a paper guide member that guides the paper on the outer peripheral surface of the roller; and a paper guide member that is placed between a first position for guiding the paper to a printing position and a second position for guiding the paper during printing. 1. A recording device comprising: a drive means that rotates back and forth at (2) A patent claim characterized in that the paper guide member is arranged so as to close the print position when in the first position and open the print position when in the second position. The recording device according to scope 1. (3) The drive means includes a paper sensor that detects the presence or absence of paper near the print position, and controls the drive of the paper guide member based on the detection result of the paper sensor. Recording device as described in section. (4) When the paper sensor detects the absence of paper in the vicinity of the print position, the driving means brings the paper guide member to the first position, and the paper sensor detects the presence of paper in the vicinity of the print position. 4. The recording apparatus according to claim 3, wherein the recording apparatus moves to bring the paper guide member to the second position when the paper guide member is in the second position.