JPH10138527A - Ink jet printer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable continuous multicolor printing over a long time at a high speed. SOLUTION: A drum 10 rotatable at a constant peripheral speed, a medium supply means 290 supplying a printing medium M to the drum 10, a negative pressure establishing means 30 making the pressure in the drum 10 negative and respective color nozzle units 200 arranged so as to be positionally shifted in the rotary direction of the drum 10 and having a large number of ink jet nozzles 207 are provided and the printing medium M supplied from the medium supply means 90 can be held to the outer peripheral surface 11 of the drum 10 by utilizing the negative pressure in the drum 10 through the suction holes 12 made through the drum 10 and inks are sprayed on the printing medium M during the rotary movement along with the drum 10 from the selected ink jet nozzles 207 of the color nozzle units 200 to execute high speed color printing.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ink jet printer capable of high-speed multi-color printing and continuous printing operation on a large number of sheets.

[0002]

2. Description of the Related Art Along with the spread of personal computers, printers for color printing have been spreading. Many color printers are known as serial type inkjet printers.

Referring to FIG. 15, an ink jet printer 500 includes a print head 501, a moving unit 510 for reciprocating the print head 501 in the X direction shown in FIG. 15A, a control unit and a paper feeding unit (all not shown). Is formed from.

[0004] The print head 501 includes a head case 503.
Consisting of nozzle units 502 for each color stored in
The nozzle unit 502 for each color has Y shown in FIG.
It has a large number of ink jet nozzles for each color arranged at a pitch P (1/300 inch) necessary for obtaining a predetermined resolution (for example, 300 dpi) in the direction. Each ink jet nozzle is directed downward, and can spray each color ink on a sheet (printing medium) M which is fed downward by one line in the sheet longitudinal direction, that is, in the Y direction shown in FIG. 15B.

[0005] In this specification, "printing" includes:
Drawing (printing) of images and the like in addition to characters and symbols is also included.

[0006] An ink cassette 504 is detachably attached to the head case 503. Generally, there are two integrated ink cassettes for each color (Y, M, C) and an ink cassette for black (B).

The moving means 510 includes a carrier 505 on which the head case 503 can be mounted, a guide rod 511,
A sprocket 512 and a timing belt 513,
The print head 501 is formed by a stepping motor (not shown) or the like, and can reciprocate in the X direction in the paper width direction.

In the ink jet printer 500, when the paper M is supplied in the Y direction, the carrier 505 is moved forward in the X direction at a predetermined speed along the guide rod 511, and the color ink is sprayed from the ink jet nozzles for each color. Perform printing (printing). When the one-line printing is completed, the carrier 505 is moved backward, and then the sheet M is fed one line and moved forward again to proceed to the two-line printing. Less than,
By repeating this, one sheet of paper can be printed in color. The paper M on which color printing has been performed is discharged to a discharge space S on the mounting table at the front side of the printer.

A laser type color printer is known as a serial type ink jet printer. In FIG. 16, a laser color printer 600
Are process means 610 for each color (yellow Y, magenta M, cyan C, black B) in the main body case 601.
Y, 610M, 610C, and 610B are arranged in the Y direction, and the paper M is transported in the Y direction through each unit 610 using the transport unit 620.

Each process means 610 includes a photosensitive drum 61
1 (Y, M, C, B) around the laser beam emitter,
A charging device, a developing device, a transfer device, a waste toner collecting device, a static eliminator, and the like are provided, and each color is printed (printed) on the paper M. Specifically, an electrostatic latent image is drawn on the photosensitive drum 611, and each color toner is attached to this. Then, the toner image is transferred onto the sheet M using a transfer device, and is fixed using a heat fixing device (not shown) at the most downstream side in the Y direction.

[0011]

By the way, color printing using the ink jet printer 500 is very slow. It takes, for example, 5 to 10 minutes or more to perform high-resolution color printing on one sheet (for example, A4 size). In some cases, the printing speed is higher than the above value by reducing the size of the ink cassette. However, this method is meaningless because the interval for ink replacement is short and a continuous printing operation of, for example, 200 or more sheets cannot be performed. Further, since the carrier 505 on which the large ink cassette 504 is mounted is repeatedly reciprocated in the X direction, the noise is high and it is difficult to eliminate the noise.

On the other hand, a laser color printer 60
A value of 0 indicates that A4 size color printing can be performed in, for example, 15 to 20 seconds. That is, the number of sheets that can be printed in one minute during continuous printing is four. That is, 4 ppm
It is. In addition, since the photosensitive drum 611 is in a rotational motion and the paper is continuously fed in one direction (Y), the noise is relatively low. However, expensive process means 610
Must be quadrupled, which is large and costly.

Thus, the ink jet printer 500
Then, for example, there is no problem when printing several postcards at home, but the required printing speed for colorization in a general office cannot be satisfied. Further, the laser color printer 600 cannot be sufficiently filled.

SUMMARY OF THE INVENTION An object of the present invention is to provide an ink jet printer capable of multicolor printing at a high speed and capable of continuously printing many sheets.

[0015]

The color printers (500, 600) having the above-mentioned conventional structure are analyzed in terms of printing speed.

First, for example, considering printing on A4 size paper (surface), the conventional ink jet printer 500 prints one line while reciprocating the nozzle unit over the entire length in the line (X) direction, and after printing one line, Move to the next row via feed in column (Y) direction. Therefore, it takes 5 to 10 minutes to complete the printing of the surface. On the other hand, in the case of the laser printer 600, one line is printed so as to be printable by a high-speed line (X) feed, which is a main scan by a laser beam, and the next line is moved to the next line by using a column (Y) direction feed by drum rotation. Move on.
Therefore, although the printing of the surface is completed earlier than the case of the ink jet printer 500, the cleaning of the remaining toner on the outer peripheral surface (photosensitive surface) of the drum, the removal of electricity, the recharging, etc. must be performed to complete the printing of one surface. . That is,
Since the outer peripheral surface of the drum is reused many times, there is a certain restriction in increasing the rotation speed of the drum, so that it is limited to about 15 seconds.

Thus, any of the printers 500, 6
00 is also a concept of completing printing of column printing as a result of stacking of line printing. In other words, it can be estimated that if the line direction and the column direction are simultaneously advanced, the printing speed can be significantly increased. Therefore, first, the conventional printers 500 and 600
We will analyze in more detail the factors that hinder printing speedup and discuss the feasibility of the simultaneous progress method.

The ink jet printer 500 is based on the premise that the nozzle units 502 for each color are reciprocated over the entire width of the sheet M in the X direction, so that the nozzle units 502 for each color and the ink cassette 504 are integrated. . In other words, since the nozzle unit 502 for each color and the ink cassette 504 must be integrated, the entire unit must reciprocate in the full width direction. In other words, since the entire print head 501 including the sophisticated nozzle unit 502 for each color and the large and heavy ink cassette 504 is reciprocated in the X direction, the printing is interrupted during the backward movement, so that high-speed printing is extremely difficult. And the noise increases due to the linear motion and the reversal of the moving direction.

Each of the ink jet nozzles has a pitch P (1/30) required to obtain a predetermined resolution (for example, 300 dpi) regardless of the type of the ink jet system.
(0 inch) and are arranged in the Y direction and the X direction is equivalent to one dot. In other words, in consideration of speeding up of color printing, the nozzle unit 5 for each color having a length over the width of the paper is considered.
What is necessary is to use a so-called line printer structure that prints one dot line at a time using 02. However, it is technically and costly difficult to manufacture an integrated nozzle unit 502 for each color nozzle unit that is uniform in finishing accuracy over the entire length thereof. The compromise is made by moving over the entire length in the width (X) direction.

Therefore, the time required for the start-stop-start for each carrier is much longer than the operation time (for example, 0.1 to 0.5 mSec) of each ink jet nozzle, so that the moving speed in the X direction is Can not be faster. This is an obstacle to speeding up color printing. At the same time, the print quality is degraded due to the feed error.

Therefore, as one concept, for example, the conventional nozzle unit 502 for each color is urged as a nozzle unit element for each color, and a plurality of nozzle unit elements for each color are referred to as Y.
It is conceivable to construct a simulated line printer structure by displacing in the X direction and partially arranging in the X direction. In this way, the pitch P between the inkjet nozzles of each nozzle unit element is set to 1/75 inch, for example, and the inkjet nozzles are reciprocated synchronously in the X direction while moving one pitch within the pitch P (1/75 inch).
If you print every / 300 inch, the resolution is 30
The time for one line dot at 0 dpi is about 0.4 seconds (= 0.1
mSec × 4 dots). That is, logically, Y
For example, one sheet of 3000 dots can be printed in about 1.2 seconds.

However, a plurality of nozzle units (elements) for each color integrated with the large and heavy ink cassette 504
It is not realistic to arrange a part of them in the X direction while arranging them in the Y direction. In addition, the intermittent paper feed in the Y direction is also a linear motion and the start-stop operation is repeated.
It also causes noise.

This can be understood as a reversal of the difficulty in increasing the speed of color printing from the fact that the conventional ink jet printer (500) leaves the printed paper M in the discharge space S as it were. In other words, the idea is to naturally dry the ink on the previous paper M by using the long time required until the end of color printing on the next paper M. Therefore, since it is meaningless to set, for example, 30 or more sheets M, the apparatus is not configured to be able to set 30 or more sheets M.

As another concept, a plurality of (N) nozzle units for each color are separated in the X direction and reciprocated in the X direction by 1 / N of the entire width of the print medium. It is possible. However, in a state where the large and heavy ink cassette 504 is integrally mounted, it is not practical in view of the necessity of adding or modifying a mechanism accompanying the ink cassette 504.

On the other hand, in the case of the laser color printer 600, since the rotational movement of the photosensitive drum 611 is used, the speed can be increased at least five times or more compared to the inkjet printer 500 with low noise. However, in general, the diameter of the photosensitive drum 611 is, for example, 20 mm and about 4 ppm from the viewpoint of demand for miniaturization and cost reduction. Therefore, the color printing time for one A4 size sheet is, for example, 15 seconds. As described above, a color printing speed several times to several tens of times higher than that of the ink jet printer 500 can be achieved, but it is extremely difficult to respond to a request to perform color printing of one A4 size sheet in 10 seconds or less, for example. . In addition, the problem of increasing the size cannot be solved.

The ink jet printer 50
Assuming that 0 is adopted, the relative movement of the nozzle unit 502 for each color and the paper M in the Y direction is preferably a rotational movement with respect to a linear movement, and the relative movement in the X direction is set to a high speed. Conventional inkjet printer 5 if color printing in the Y (column) direction is possible
It should be possible to achieve a significantly higher printing speed as compared with 00. Noise can also be reduced. In addition, if the printing of each color can be performed using one drum during the relative rotation movement of the nozzle unit 502 for each color and the paper M, the size can be reduced to 1/4 times as compared with the laser color printer 600. It is. In addition, it is considered that the drying of the ink on the paper M can be promoted by utilizing the relative flow with the ambient outside air during the relative rotation transfer.

Here, if the paper M can be rotated at a high speed in the longitudinal (Y) direction, it is possible to wipe out the factor that hinders the high-speed color printing related to the feeding of the paper M and the nozzle unit for each color in the Y direction. In particular, if the paper M is rotated by a drum or the like, the nozzle units for each color can be easily displaced in the Y direction (rotation direction) instead of the X direction. It becomes possible. Therefore, it is possible to form an apparently integrated nozzle unit for each color by directly or indirectly arranging a plurality of short and small color nozzle unit elements in series in the X direction. That is, an apparent line printer structure can be constructed.

Further, if the ink cassette can be arranged at a remote position, the weight of the entire print head can be reduced, and from this point, the moving speed in the X direction can be further increased. In other words, it is possible to wipe out the most influential factor for speeding up color printing, which is related to the feeding of the paper M and the nozzle unit for each color in the X direction. In addition, the short and small nozzle unit elements for each color can be easily realized in terms of both technical and cost aspects. Further, since the size of the ink cassette can be increased, a continuous printing operation can be performed for a large number of sheets (for example, 200 sheets or more).

According to the results of the above examination, if the print medium can be securely held on the drum, the printing in the row direction and the printing in the column direction can proceed at the same time to achieve high-speed printing.

Thus, according to the present invention, the supplied printing medium is formed so as to be held on the drum by utilizing the negative pressure, and the relative movement (rotational movement) of the printing medium and the nozzle unit for each color in the longitudinal direction of the printing medium. It is apparent that the nozzle unit for each color can be integrally or integrally formed as a combination of a plurality of nozzle unit elements for each color that can reciprocate a short distance of, for example, a pitch between the inkjet nozzles by utilizing The line printer structure can be realized, and the reciprocal movement in the X direction and the relative rotational movement in the Y direction can be accelerated, while continuous printing can be performed using the nozzle unit for each color during the relative rotational movement. In addition, it is formed to enable continuous printing operation.

That is, a first aspect of the present invention provides a drum rotatable at a constant peripheral speed, a medium supply means for supplying a printing medium to the drum, a negative pressure establishing means for reducing the pressure in the drum, and a drum. A nozzle unit for each color having a number of ink jet nozzles, each of which is displaced in the rotational direction of the drum and provided with a plurality of ink jet nozzles. The print medium is formed so as to be able to be sucked and held on the outer peripheral surface of the drum, and is formed so that color printing can be executed while spraying ink from the selected inkjet nozzle of each color nozzle unit onto the print medium rotating and moving with the drum. , Characterized in that.

In this invention, the print medium supplied from the medium supply means is suction-held on the drum by utilizing the negative pressure established through the suction hole in the drum by the negative pressure establishment means. When the drum is rotated at a constant peripheral speed, the nozzle units for each color, which are displaced in the rotation direction of the drum, and the print medium relatively rotate and move in the longitudinal direction of the print medium. It has extremely low noise and can rotate and move at high speed.
Therefore, for example, each color nozzle unit element that forms each color nozzle unit that is misaligned and arranged in the drum rotation direction, using the selected inkjet nozzle for each color of the integrated color nozzle unit in the width direction of the print medium, or Since the nozzle units for each color can be simultaneously moved in the direction of the drum axis in the drum axis direction, for example, synchronously by the pitch between the inkjet nozzles, it is possible to print on the rotating print medium M using the selected inkjet nozzles for each color. Multicolor printing can be performed at high speed, and a continuous printing operation of many sheets is possible.

Further, the invention according to claim 2 is characterized in that the negative pressure establishing means is provided on an end face of the drum and fixedly disposed corresponding to a suction port communicating with a space in the drum; And a suction fan that sucks air from the corresponding suction port to make the inside of the drum have a negative pressure.

In this invention, when the suction fan is rotated during rotation of the drum, the air in the space inside the drum is sucked through the suction port on the drum side and the corresponding suction port on the stationary side. Therefore, a negative pressure can be formed in the drum, and the print medium can be held using the negative pressure. Therefore, claim 1
In addition to providing the same operation and effect as in the case of the invention, the structure can be realized with a simple structure and at low cost.

[0035]

Embodiments of the present invention will be described below with reference to the drawings. This inkjet printer is shown in FIG.
-Drum 1 rotatable at a constant peripheral speed as shown in FIG.
0, medium supply means 290 for supplying the print medium M to the drum 10, and negative pressure establishing means 30 for making the inside of the drum a negative pressure.
And a nozzle unit 200 for each color, which is displaced in the rotation direction of the drum 10 and has a large number of ink jet nozzles 207, respectively, and uses a negative pressure in the drum through a suction hole 12 penetrating inside and outside the drum. The print medium M supplied from the medium supply means 90 is formed on the outer peripheral surface 11 of
In addition, color printing can be performed while spraying ink from the selected ink jet nozzle 207 of the nozzle unit 200 for each color onto the print medium M that is rotating and moving.

First, the overall configuration will be described with reference to FIG. A medium supply means 90 is provided on one (right) side of the high-speed rotatable drum 10, and a medium discharge / conveyance means 160 is provided on the other (left) side. The nozzle units 200C, 200M, 200Y, and 200B for the respective colors are displaced in the rotation (Y) direction of the drum 10, and a medium discharge / convey means 160 is provided above the nozzle units.

The medium supply means 90 can supply the print medium M fed from the paper supply means 60 to the drum 10 after correcting the attitude of the print medium M. The supplied print medium M is held on the outer peripheral surface 11 of the drum 10 by the medium holding means 20 including the negative pressure establishing means 31.

The print medium M after color printing is peeled off from the drum 10 (11) by the medium peeling means 140 (141) and delivered to the medium discharge / conveying means 160 via the medium delivering means (141). The sheet is discharged and conveyed in a predetermined direction by the discharge and conveyance means 160. The direction switching unit 190 is capable of selectively switching between the discharge conveyance with the print surface facing up to the discharge tray 192 and the discharge conveyance with the print surface facing down to the upper discharge tray 193.

An ink drying means 1 is provided around the drum 10.
30 (131, 132) for directly or indirectly drying the ink on the printing medium M held on the drum 10 for speeding up printing, and for facilitating charging of the supplied printing medium M, etc. Can be forcibly preheated. Further, an ink drying unit 181 for forcibly drying the ink on the print medium M is provided at the end (left) side of the medium discharge / conveyance unit 160 in order to complete the drying of the ink.

Each color nozzle unit 200C, 200
M, 200Y, 200B and the ink supply means 210 are arranged separately. Therefore, the unit moving means 11
0 indicates that the nozzle unit 200 for each color, which has been reduced in size and weight, can be rapidly reciprocated in the width (X) direction of the print medium M, that is, in the axial direction of the drum 10. In addition, the nozzle units 200 for each color can be moved back and forth in the left-right direction in FIG. 2 to the drum 10 (11) by the moving unit 220, and the ink jet nozzles 207 for each color are covered with the cap 246 in the separated state to dry the ink. It is formed to be preventable. The cap 246 is moved up and down by cap lifting means 240. In addition, the drive is controlled by the control unit 250 as a whole.

Each of these means is stored in the main body case 1. The upper case 2 (discharge roller 2R) forming the upper discharge tray 193 can be opened as shown by a two-dot chain line in FIG.

In the drum 10, the printing medium M (plain paper, OHP paper, etc.) wound and held on the outer peripheral surface 11 is Y-shaped.
In this embodiment, the drum d has a diameter d of 130 mm and a drum axis (shaft 10).
It is possible to rotate at a constant rotation speed (120 rpm) enabling continuous printing of 20 ppm around S). That is, the drum 10 can be rotated once in 0.5 seconds. The drum 10 is driven to rotate by a main motor 93 composed of a servomotor having excellent high-speed response and constant speed.

More specifically, as shown in FIG.
The shaft 10S is rotatably mounted on the left and right brackets 5L and 5R via bearings.
Is rotated about an axis (10S) via a sprocket, a timing belt or a gear.

That is, the speed at which the print medium M is moved in the column (Y) direction is significantly higher than that of the conventional example (600) and is constant at a constant peripheral speed (816 mm / Sec = 120π).
d / 60). This high peripheral speed can also be used to promote natural drying of the ink. Since the outer peripheral length is 408 mm (= πd), the A4 size (length:
(297 mm, width: 210 mm) can be held with a margin in the length direction thereof, and a print medium (M) longer than that can be held. The length in the drum axis direction is about 220 mm, which is longer than the A4 size (210 mm). The drum 10 has a hollow (10E) cylindrical shape such as an aluminum alloy and is grounded.

The diameter d of the drum 10 is preferably 100 mm or more in order to obtain a high peripheral speed capable of holding a print medium M of A4 size or more and promoting ink drying.

Since each color nozzle unit 200 is provided separately from each ink supply means 210 (ink cassette 211), it can be integrally formed as a combination of a plurality (N) of color nozzle unit elements 205. In this embodiment, in order to secure technical and cost advantages, four (= N) nozzle unit elements 205 shown in FIG.
A, 205B, 205C, and 205D are arranged as being displaced in the rotational movement (Y) direction of the drum 10. In other words, the nozzle unit 200 for each color
As shown in FIG. 4, N (=) in the drum axis (X) direction.
4) It is integrally formed from the divided nozzle unit elements 205A to 205D. Each nozzle unit element 205
The length of the divided lines of A, 205B, 205C, 205D is
These are S1, S2, S3, and S4 shown in FIG.

More specifically, the nozzle unit element 205A,
The nozzle unit 205C and the nozzle unit elements 205B, 205D are spaced apart in the drum axis direction, that is, in the X direction, and displaced in the Y direction via the connection support bar 204, and are indirectly shifted in the X direction as a whole in the Y direction. Are arranged in a so-called staggered shape.

However, the pitch PT between the ink jet nozzles is
Can be arbitrarily selected, so that if the pitch PT between inkjet nozzles is increased, each nozzle unit 200 can be formed as an integral type extending in the X direction.

Each nozzle unit element (205A) includes:
A large number (159) of inkjet nozzles 207a to 207n are arranged at a constant pitch PT (1/75 inch) within a length Lxa (2.11 inches). Height (Figure 4
Ly in the vertical direction) is 9 mm. X (X1, X2)
Nozzles 2 at each end of each nozzle unit element 205 adjacent in the direction and displaced in the Y direction
A constant pitch PT (1/75 inch) is maintained between 07n and 207a.

The nozzle unit 200 for each color is Y
It is arranged so as to be displaced in the direction by a predetermined pitch Yp (for example, 20 mm). In this embodiment, the arrangement order from the upstream side to the downstream side in the Y direction is as follows: cyan C, magenta M, yellow-Y, black B (200C, 200C).
M, 200Y, 200B).

The multicolor nozzle unit 200 has four nozzles.
Although they are used for colors (C, M, Y, B), they can be displaced in the Y direction, so that it is easy to arrange more than six colors, for example, by adding light red and blue. Thus, it is possible to execute clearer multi-color printing with higher quality.

Further, each color nozzle unit 200C,
Each of the inkjet nozzles (for example, 207a) corresponding to 200M, 200Y, and 200B, that is, each of the nozzle unit elements 205 is at the same position (the position on F1 in FIG. 4) in the drum axis (X) direction. Thus, in this embodiment, the mounting member 11 shown in FIG.
2 and is attached to the reciprocating mechanism 111 via. Therefore, each color dot (inkjet nozzle) can be accurately overlapped in the X direction. That is,
Each column is identical.

Furthermore, the nozzle unit 200 for each color
Since C, 200M, 200Y, and 200B are displaced in the rotation (Y) direction of the drum 10, each ink jet nozzle 207 is disposed on each normal line to the drum 10 so that the drum 10, that is, the print medium M The size and shape of the dots D formed by the sprayed color ink are made the same to maintain and improve the printing quality. The gap between the tip (spray hole) of each ink jet nozzle 207 and the drum 10 is, for example, 1 mm during the printing operation.

As shown in FIG. 11, an ink supply means 210 for supplying the respective color inks to the respective color nozzle units 200 includes an ink tank 213 having a filter 214 and a liquid level fixing means provided in the ink tank 213. 2
12, an ink supply tube 215 connecting the ink tank 213 and the nozzle unit 200 (205), and an urging means 21.
6. Ink return tube 217 and tube opening / closing means 2
18 The ink cassette 211 has a larger amount (for example, 200C) than the conventional example ((10 to 20CC)).
C or more).

When each urging means 216 is driven in a state where the ink return tube 217 is closed by each tube opening / closing means 218, the color ink is added from the ink tank 213 into the nozzle unit 200 for each color (ink buffer 206). Pressure can be supplied (energized), and by priming or spitting as it is, air bleeding near each nozzle and clogging of each nozzle can be prevented. After that, if the ink return tube 217 is opened,
Air can be removed from the ink buffer 206. further,
The urging means 216 is stopped and the tube opening / closing means 218
When printing is performed with the ink return tube 217 opened, the ink reduced by the ink jet is automatically supplied from the ink tank 213 to the ink buffer 206 via the ink return tube 217 by the capillary effect. The ink level in the ink tank 213 is
The liquid level is kept constant by the liquid level fixing means 212.

As shown in FIG. 12, each biasing means 216
A rotary type having a plurality of (four) pressing rollers 216R shown in FIG. 2B and rotated by a motor 216M is engaged with each ink supply tube 215 (rotation pressing engagement) to convert each color ink into the corresponding color. (Pressurized supply) to the nozzle unit 200 side. The tube opening / closing means 218 is a rotary type having one pressing roller 218R. In addition, it is good also as a structure by a solenoid piece etc.

Further, in this embodiment, the height difference between the ink tank 213 for each color (specifically, the ink liquid level) and the ink discharge port (spray hole) of the nozzle unit 200 for each color is slightly different depending on the ink characteristics. Adjusted. This is to stabilize even higher quality printing by making the ink jet characteristics (meniscus) uniform. The ink tanks 213 for each color are disposed at a position lower than the ink discharge ports of the nozzle unit 200 for each color, and the ink tanks 213 for each color are opened to the atmosphere during the printing operation.

The spray control element 208 is appropriately selected in accordance with the ink jet system.
A predetermined amount of ink can be sprayed by using the shear deformation of 07. The operation time required from the end of the printing of the previous dot to the end of the printing of the subsequent dot is 0.1 mSec (1 msec).
0 KHz). It should be noted that an ink-jet method such as electric / thermal conversion, electric / mechanical conversion, etc. may be adopted.

As described above, since the ink tank 213 and the ink cassette 211 having a large capacity, a large weight and a large size can be disposed separately from the nozzle units 200 for each color, the nozzle unit 200 for each color (the nozzle unit element 205). Can be densely arranged in the X direction and the Y direction, and the size and weight can be reduced as compared with the case of the conventional example (500).
Further, since the interval for replacing the ink cassette can be lengthened, the continuous printing operation time can be greatly increased.

Therefore, each color nozzle unit 200
(Nozzle unit element 205) can be synchronously moved in the X direction at a light load and at a high speed. The unit moving means 110 for this purpose is formed of a reciprocating mechanism 111 and a motor unit 121 having a reciprocating rod 122 shown in FIGS. 2 and 9, and performs reciprocating movement in the X (X1, X2) direction quickly and smoothly. I can do it. Nozzle unit 20 for each color
Numeral 0 is attached to the reciprocating mechanism 111 via the attachment member 112. The whole is moved forward and backward by the forward and backward moving means 220 shown in FIG.

As shown in FIG. 9, the reciprocating movement mechanism 111
A pair of guide rails 11 attached to the base 111B
A table 111T is slidably mounted on 1G, and the table 111T is urged downward by a pair of left and right springs 111SP so as to abut against a pair of left and right stoppers 111S so as to be in a fixed position in a normal state. It is formed. The motor unit 121 is fixedly mounted on the frame 111F, and moves the nozzle unit 200 for each color fixed on the table 111T against the urging force of each spring 111SP to the position indicated by the two-dot chain line in the X direction (X1).
Can be done. The return (X2) is for each spring 1
It is performed by the urging force of 11SP.

The motor unit 121 has a front bearing of a general stepping motor having a screw structure so that the rotational force is directly propelled by a reciprocating rod (12).
2) It is formed so as to be able to convert it into the reciprocating motion.
In this embodiment, a linear stepping actuator (SPS20E series, manufactured by Copal Electronics Co., Ltd.) is used.

That is, the reciprocating motion of the reciprocating rod 122, which can switch the direction of rotation of the motor (121) by utilizing the rotational force of one motor (121) and switching the direction of rotation of the motor (121), is utilized and the reciprocating mechanism 111 is used. And nozzle units 200C, 200M, 200Y, 2 for each color.
00B can be synchronously reciprocated in the X (X1, X2) direction. Therefore, since the timing belt and the like can be wiped out as in the conventional example (500), noise can be eliminated.

Further, the motor unit 121 is of a variable rotation speed type, and the rotation speed switching control means (250) controls the forward movement (X1) during the color printing operation and the backward movement (X2) after the color printing operation. ) The rotation speed can be switched at a high speed. This is for further increasing the printing speed.

Further, it is formed to return within two rotations of the drum from the separation after the end of the previous printing to the suction of the next printing medium M, and to wait for the next printing.

The motor unit 121 is connected to the table 1
It may be attached to a table that is moved below the 11T by the driving of the advance / retreat moving means 220 and connected to the table 111T via a link mechanism. In this way, the load on the motor unit 121 can be further reduced.

Thus, as shown in FIG. 1, each of the nozzle unit elements 205A, 205B, 205C, and 205D is moved in the X1 direction in a pitch P between the inkjet nozzles.
T (1/75 inch) reciprocating movement and printing during forward movement are performed for each divided line (S
Considering that only the first one dot (D1) of (1, S2, S3, S4) is printed, it is understood that printing can be performed within the operation time (0.1 mSec) of the inkjet nozzle 207. .

However, if this is repeated in the Y (column) direction by, for example, 3000 dots as in the case of the conventional example (500), a remarkable increase in speed cannot be achieved. Here, each divided line (52.5) determined by dividing the length of one line (L) (for example, A4 size width 210 mm) by N (= 4).
mm) Within S1, S2, S3, and S4, the nozzle unit element (for example, from a front dot (for example, D1) separated by a pitch PT (1/75 inch) between inkjet nozzles to a rear dot (for example, D2)) 205A) was selected while utilizing the high-speed rotation (one rotation in 0.5 seconds) in the column (Y) direction of the print medium M while the paper was advanced in the X1 direction, that is, advanced by 1/300 inch. While the ink is sprayed (jetted) from the inkjet nozzle 207 in the nozzle unit element 205A, each dot (（D1n−1, D1n) belonging to the row (F1) corresponding to the previous dot D1 is taken until the drum 10 makes one rotation. When color printing is performed, printing in the row (X) direction and printing in the column (Y) direction can proceed simultaneously. That is, one line equivalent to 300 dpi can be printed in 0.5 seconds.

Therefore, each ink jet nozzle 20
7 can print four rows while the drum 10 rotates four times.
That is, each nozzle unit 205 can print all the columns belonging to the divided row (S1, S2, S3, S4) during four rotations. That is, the entire surface can be printed in 2 seconds (= 0.5 seconds × 4). With room,
Considering that each rotation (0.5 seconds) is used for attaching and detaching the print medium M before and after the start of printing, one A4 size sheet is replaced by 3 (=
Multicolor printing can be performed at a remarkably high speed of 2 + 1) seconds or less.

The nozzle units 200 for each color (20
5) Pitch PT between each inkjet nozzle (for example,
By moving (forwarding) by 1 / N (for example, 8) of 1/75 inch in the X1 direction and using N (= 8) rotations of the drum, the pitch PT ( Resolution (75d) determined by 1/75 inch
Multicolor printing can be performed at a resolution (600 dpi) that is N (= 8) times as large as that of the image data of the image data of the image data. That is, the nozzle unit 200 (205) for each color utilizes the high-speed rotational movement of the drum 10 regardless of the pitch PT between the ink nozzles.
By switching the amount of synchronous movement in the X1 direction and the number of rotations N of the drum, it is possible to switch the operation to a desired resolution, and to manufacture the nozzle units 200 (205) for each color technically easily and at lower cost. It is possible.

Further, depending on the operation method, if the high-speed printing of the print medium (surface) M is used, the pitch PT between the ink jet nozzles can be adjusted to a predetermined resolution (for example, 300 dp).
The reference pitch PTp (1/1) shown in FIG.
300 inches), which is 1/75 inch of N (4) times, and the nozzle unit 200 (205) for each color is moved in the direction of the drum axis (X) by the reference pitch PTp (1/300) while the drum 10 makes one rotation. Inch) only move (forward)
And by rotating the drum 10 N (= 4), the nozzle unit 200 for each color of resolution (75 dpi)
Using (205), multicolor printing with a predetermined resolution (300 dpi) can be performed.

The feeding means 60 feeds the printing medium M one by one to the medium feeding means 90 side, and can be opened and closed (freely) on the side 3 of the main body case 1 as shown in FIGS. A manual feeding means 61 for feeding, by using a feeding roller 65, what is manually inserted into the manual feeding tray 62 mounted on the cassette 7;
A cassette feeding means 71 for feeding the print medium M on the sheet 2 (mounting plate 73) one by one using a feeding roller 75, and the feeding rollers 65 and 75 are formed so as to be selectively fed. Feed switching means 81. Cassette 72 (73)
Can accommodate 500 print media M.

The feed switching means 81 switches between the drive source (rotational power) and its rotation direction (65, 7).
5) is formed to be switchable. The drive source is obtained from a motor 82 capable of reversible rotation switching via a gear train 83. Further, a start / stop state switching means 84 for selectively switching between a feed drive state and a feed stop state is provided.

That is, when the motor 82 is switched in one rotation direction, the one-way clutch 65C rotates the feed roller 65, and when switched in the other rotation direction, the one-way clutch 75C rotates the feed roller 75. The start / stop state switching means 84 includes an actuator 85
And a switching mechanism 86. The switching mechanism 86 includes a lever 8
7 (pin 87P, engaging pin 87K), lever 88 (pin 88P), lever 89 (pin 89P) and the like. The operation of the actuator 85 causes the feed roller 75 to move upward and away from the print medium M, and
The friction plate 65F corresponding to the holder 65H (pin 65P)
Start (approach) by approaching downward through the remote
The state and the stop (separation) state can be switched.

Here, the medium supply means 90 is a pair of supply rollers (91, 92) having a posture correcting function shown in FIG.
The print medium M formed from the unit and fed from the feeding means 60 can be supplied to the drum 10 at a predetermined timing. The supply speed is a speed corresponding to the peripheral speed of the drum 10.

The posture is corrected by causing the leading end Mf (see FIG. 1) of the fed print medium M to collide with (abut against) the contact portions 99 of the supply rollers 91 and 92 in the stopped state. This is executed by aligning the tip Mf with the straight line formed by the contact portion 99 extending in the direction of the drum axis (X). Further, a bending space SP shown in FIG. 2 is provided between the feeding means 60 and the medium supply means 90 so that the bending of the print medium M is allowed.

That is, the feed amount of the feed roller 65 (75) at one time is made slightly larger than the distance between the feed roller 65 (75) and the two feed rollers 91 and 92, and The elastic deformation in the middle of M is positively generated, and the pressing force of the tip Mf against the contact portion 99 is strengthened by the elastic force, so that the posture can be more reliably corrected.

At least one of the supply roller units (90) [91, (92)] is provided with a supply power applying means (9) comprising a main motor 93, a gear train, a clutch and the like.
The supply power for rotation is applied from 3). After the posture correction, the supply power applying means (93) sends the print medium M to the drum 10 side by an amount corresponding to the elastic deflection by the supply rollers 91 and 92 by the supply roller rotation drive control means (250). More specifically, the print medium M is sent until the leading end of the print medium M is detected by a sensor (not shown). That is, the leading end Mf of the print medium M
The two sides are engaged by the two supply rollers 91 and 92 to set the standby state.

During the standby state (standby), the start / stop state switching means 84 operates to supply the supply roller 75.
From the print medium M and the friction plate 65F
Move away from 5. Therefore, feeding can be performed at any time, and it is possible to completely prevent the next printing medium M from being erroneously fed.

That is, the supply roller rotation drive control means (250) prohibits the application of the supply rotation power until the attitude of the print medium M is corrected, and permits the application of the supply rotation power after the attitude correction. Specifically, the time is controlled by the time of the feeding operation of the feeding means 60. Print medium M to drum 10
This is because the supply can be made without skewing to the side. The supply power may be obtained from the motor 82.

Further, the supply timing adjustment control means 250 for adjusting the timing with the drum 10 side has the rotational position of the drum 10 set in advance by the position detection means 100 including the light emitting device and the light receiving device shown in FIG. When the set position is reached, the print medium M is supplied by engaging with (for example, inputting a drive command) with the medium supply unit 90, that is, the supply power supply unit (93).

Here, the medium holding means 20 is means for holding the print medium M on the outer peripheral surface 11 of the drum 10 and is carried out by negative pressure suction holding, and in this embodiment, mechanical means as auxiliary means. Retention and charge adsorption retention are introduced.

That is, the negative pressure suction holding means 21 forms a negative pressure in the drum 10 (hollow portion 10E, that is, a space in the drum) by the negative pressure
The print medium M is formed so as to be able to be suction-held under negative pressure through a large number of suction holes 12 penetrating through the inside and outside in the radial direction.

As shown in FIG. 6, the negative pressure establishing means 31 includes a corresponding suction port 34 corresponding to the suction port 14 on the drum 10 side,
A suction fan 32 that sucks air to establish a negative pressure in the drum (hollow portion 10E) from the corresponding suction port 34 through a duct 35 through a duct 35 is formed. The duct 35
The corresponding suction port 34 may be provided on the suction port 14 side.

The suction port 14 is a side end plate (end face) of the drum 10.
15R, the corresponding suction port 34 corresponds to the suction port 14 and is fixed to the bracket 5R in the main body case 1. Drum 10 (15R) and negative pressure establishing means 30
(5R) means that it approaches in the drum axis direction but does not contact. Therefore, the rotational load of the drum 10 can be reduced. Further, the gap between the two 15R, 15R is useful for reducing the suction fan load fluctuation between when the print medium M is suctioned under negative pressure and when it is not. The side end plate (end surface) 15L is a blind plate.

The holding claw holding means 41 for mechanical holding as an auxiliary means, as shown in FIGS. 7 and 8, holds the peripheral portion of the supplied printing medium M. In this example, the front end side of the print medium M is formed to be held between the drum 10 by the holding claws 42. In this embodiment, the sheet is held at a plurality of points (tips) including both ends in the direction of the drum axis (X).

That is, the holding claw holding means 41 comprises the holding claw 42, the always holding mechanism 43, the always releasing lock mechanism 44, the lock releasing mechanism 45, and the lock returning mechanism 46. The release lock mechanism 44 is mounted on one end of the drum 10 which is a movable side, and the lock release mechanism 45 and the lock return mechanism 46 are attached to a bracket (not shown) in the main body case 1 which is a stationary side. In addition, the lock release mechanism 45 and the lock return mechanism 46 perform the pinching and the pinching release of the pinching claw 42 in cooperation with the constant pinching mechanism 43 and the constant release lock mechanism 44 while skillfully utilizing the rotational movement of the drum 10. It is formed.

The holding claw 42 includes a claw 42F, an engaging portion 42C,
It has a sector gear 42G and is mounted to be rotatable about a pin 42P. The pinching mechanism 43 always includes a pin 43P.
Lever 43L (base end portion 43B, front end portion 43F) rotatable around the center, a sector gear 43G provided on the front end portion 43F and meshing with the sector gear 42G, and a base end portion 4G.
Spring 43 stretched between 3B and fixed portion 43R
The holding claw 42 is always kept in the holding state shown by the two-dot chain line in FIG. 7 by using the urging force (tensile force) of the spring 43SP.

The normally-release lock mechanism 44 is composed of a lock lever 44L that can rotate about a pin 44P, and an engagement groove 44C of the lock lever 44L is formed so as to be able to engage and disengage with an engagement portion 42C of the holding claw 42. And both 44C and 42C
Is formed so that the holding claws 42 can always be locked in the holding release state shown by the solid line.

The lock release mechanism 45 includes a pin 45 on the stationary side.
Pivotable lever (tip 45F, base 4
5B) It consists of 45L and actuator 45A. When the lever 45L is rotated clockwise about the pin 45P by the actuator 45A, the distal end 45F formed of the pin engages with the proximal end 44B of the lock lever 44L that has moved with the rotation of the drum 10. I do. Then, the lock lever 44L rotates clockwise and the pinching claw 42 is rotated.
The engagement with (42C) is released. Therefore, the holding claws 42
Is in a state where it can be held by the urging force of the spring 43SP. That is, the constantly released lock state can be released.

The lock return mechanism 46 is, as shown in FIG.
A lever 46L (a distal end 46F, a proximal end 46B) rotatable about a stationary pin 46P;
A. With this actuator 46A, the lever 46
When L is rotated clockwise around the pin 46P,
The lever 43L, which has been moved with the rotation of the drum 10, presses the distal end portion 46F of the lever 46L, which is a pin, and puts the holding claw 42 into the holding release state shown by a two-dot chain line via the sector gears 43G, 42G. Can be. Therefore, the engaging portion 42C of the holding claw 42 is moved to the lock lever 44L.
(44F) engages with the engagement groove 44C. In other words, the pinching claw 42 can be returned to the constantly pinching locked state.

The charge adsorption and holding as auxiliary means is performed by a charging means 51 shown in FIG. 2 of a charging roller system. The print medium M is charged with a positive charge, and the print medium M is attracted and held on the outer peripheral surface 11 by utilizing the charge attracting force generated between the drum 10 and the grounded drum 10.

In order to reduce the load at the time of suction, a means (not shown) for opening the nip of the supply rollers 91 and 92 is provided. In addition, the charging means 51 is connected to the drum 10
When the suction of the print medium M onto the drum 10 is completed, the drum 10 (1
It is formed so as to be separated from 1). Accordingly, it is possible to prevent the ink image formed on the print medium M from coming into contact with the ink image and disturbing the image.

Further, in order to increase the charging efficiency of the charging means 51, a preheating means for forcibly preheating the print medium M supplied to the drum 10 is provided. The preheating means in this embodiment is formed to also serve as the ink drying means 130 described below.

That is, the ink drying means 130 introduced in order to improve the long ink drying time related to the printing speed hindrance factor of the conventional example (500) is provided by utilizing the periphery of the drum 10. 2 is formed by a heat source 131 and a warm air flowing means (fan) 132, which is heated by the heat source 131 while flowing the outside air, and the warm air is blown onto the print medium M held on the drum 10 to print the printed ink. Drying is performed directly or indirectly through heating of the print medium M. Thus, if a part of the warm air flows between the medium supply means 90 and the charging means 51, the print medium M can be forcibly preheated before being supplied to the drum 10.
This preheating improves the ink riding on the print medium M.

Further, the replenishing charging means 53 provided in relation to the charging means 51 is formed so as to be able to replenish the decay of the charge attraction force accompanying the execution of color printing by ink jet. The charging means 51 can be used also as the replenishing charging means 53. In this case, the charging means 51 is formed to have a variable charging ability, and the charging ability of the charging means 51 is large during the supply of the printing medium M and the rotation of the drum 10 in the Y direction by one rotation. What is necessary is just to be able to switch small later. However, the charging means 51 in this case is the drum 10
It should be a non-contact type (for example, a corona charger) that does not contact the (print medium M).

After the color printing, the charge removing means 55
To remove the charge for adsorption. This is performed by adding a negative charge opposite to that of the charging means 51.

In this embodiment, the medium supply means 9
0 and drum 1 of print medium M by medium holding means 20
One rotation (0.5 sec) of the drum 10 is allocated for supply and holding to zero.

The printing medium M after the color printing is separated from the drum 10 (11) by the medium separating means 140 including the separating claw 141 which can be interrupted (inserted) between the drum 10 and the printing medium M shown in FIG. It is formed to be possible. The peeling claw 141 is separated from the drum 10 during the printing operation. The medium separating means 140 and the medium holding means 20 (2
A removal timing adjustment control means (250) is provided for synchronization with (1, 41).

That is, the removal timing adjustment control means (250) controls the medium holding means 20 at a predetermined timing suitable for the separation of the medium separation means 140.
The holding force of (21, 41) is removed, and thereafter, the peeling is performed by interrupting (inserting) the peeling claw 141 between the print medium M and the drum 10 (11).

The peeling claw 141 can be separated from the drum 10 (11) during color printing and can be approached (interrupted) during peeling by a link mechanism (not shown). It is formed to also serve as a medium delivery means for delivering to the 160 side. However, the medium delivery means is formed so that the print medium M can be more actively delivered to the medium discharge / conveyance means 160 side using, for example, air pressure, vacuum force, mechanical force, or the like, and is formed separately from the peeling claw 141. You may.

These removal timing adjustment control means (2
50), medium holding means 20 (51, 53, 21, 31,.
41, 55) and one rotation (0.5 sec) of the drum 10 is allocated for releasing and holding the print medium M from the drum 10 by the medium separating means 140.

Further, charging means 51, replenishing charging means 5
3, the charge removing means 55 and the medium peeling means 140 are spaced apart from the upstream side in the rotation (Y) direction of the drum 10 to the downstream side in this order as shown in FIG. It is trying to make it.

Next, the medium discharging / conveying means 160 is means for discharging / conveying the separated printing medium M in a predetermined direction. In this embodiment, as shown in FIG. 10, the medium is in contact with the non-printing surface side (back surface). It is composed of a belt conveyor 161 and a medium pressing means for pressing the print medium M toward the belt conveyor 161. Therefore, it is possible to smoothly discharge the print medium M in a desired direction after printing.

The belt conveyor 161 is shown in FIG.
As shown in (B), the separated printing medium M is
Can be discharged and conveyed at a speed corresponding to the peripheral speed of the print medium M, and after the rear end of the print medium M is separated from the drum 10, the longest time within a range that does not hinder the color printing of the next print medium M is used. The speed can be switched to low speed to discharge and transport. Natural drying of the ink can be further promoted. Therefore, the length of the belt conveyor 161 is A4
It is larger than the length of the size.

The medium pressing means comes in contact with the press belt conveyor 171 which is in contact with both sides (print prohibited area) of the medium on the print surface side and comes into contact with the print medium M in a normal state when the print medium M is floating. It is formed of a so-called star wheel 176 (see FIG. 10C) for preventing floating. 179 is a contact portion 177 of the star wheel 176
The sponge or felt is used to clean the ink attached to the surface.

An ink drying means 181 shown in FIG. 2 is provided opposite to the belt conveyor 161 and at the end thereof. The ink drying means 181 is forcibly dried on the printing surface side of the printing medium M during discharge and conveyance to complete the ink drying. It is trying to make it. The ink is dried directly or indirectly through heating of the print medium M. Therefore, the print medium M with the color printing is turned upside down by the direction switching means 190 on the discharge tray 192 which is openably and closably (freely) mounted on the side 4 of the main body case 1 as in the case of the manual feed tray 62. The discharge can be switched or the non-printing surface can be discharged upward to the upper discharge tray 193. That is, the direction switching means 19
0 can be selectively switched to one of two directions and discharged. Note that three or more directions may be formed so as to be switchable.

After the completion of the color printing, the advancing / retracting moving means 22 for moving the respective ink jet nozzles 207 of the respective color nozzle units 200 apart from and closer to the drum outer peripheral surface 11.
0 works and the nozzle units 200C, 200M,
200Y and 200B can be retreated (separated) to the left in FIG. After retreating, the cap 246 raised by the cap lifting / lowering means 240 covers each ink jet nozzle 207 to prevent the ink from drying. This cap 2
Reference numeral 46 denotes an elastically deformable seal member (for example, a hollow cylindrical body made of synthetic rubber) shown in FIG. 14, which can press the spray holes (tips) of the ink jet nozzles 207.
Therefore, each ink jet nozzle 207 is
Even if it is arranged on the normal line of 0, it can be reliably sealed.

As shown in FIG. 2, the forward / backward moving means 220 is rotatably mounted on a rack 221 provided on a table provided with the unit moving means 110 (reciprocating mechanism 111) and a bracket in the main body case 1. And a pinion 222 engaged with the rack 221.

Further, the cap lifting / lowering means 240 is
As shown in FIG. 14, one end of the link bar 243 is rotatable around the pin 243P and the other end is slidable in the guide groove 243H via the slide pin 243S. The other link bar 244 slidable in the guide groove 242H through the guide groove 242H, the tip of which can rotate around the pin 244P, and the screw shaft 2 rotated by the gear 247.
42 etc. The link bars 243 and 244 are rotatably connected at an intermediate portion by a pin 245. Therefore, if the screw shaft 242 is rotated, the lifting frame 241
Can be raised and lowered.

The lifting frame 241 has a cap 2
The waste ink receiver 231 having the attached 46 is fixedly mounted. That is, when the nozzle unit 200 for each color is moved leftward (in the direction away from the drum 10) in FIG.
Raises the cap 246. Then, the advancing / retreating means 220 moves the nozzle units 200 for each color to the right (the direction approaching the drum 10), and stops when each ink jet nozzle 207 comes into contact with each cap 246. That is, it can be covered with the cap 246.

A reference numeral 249 shown in FIG. 14 denotes a wiper blade, which is a rotating body 248 about a support shaft 248P.
To clean each ink jet nozzle 207 before being covered with the cap 246.

The waste ink collecting means 230 comprises a waste ink tank 234 including a waste ink receiver 231, a waste ink tube 232, a waste ink pump 233 and a sponge 235 shown in FIG. By increasing the internal pressure of each ink and the ink buffer 206 in each color nozzle unit 200 (205) at the time of the spit, it is possible to collect the primed inks.

Note that the control unit 250 shown in FIG.
It is formed of a computer including a CPU, a ROM, a RAM, and the like, and forms not only the print control means but also the above-described supply roller drive control means, supply timing adjustment control means, rotation speed switching control means, removal timing adjustment control means, and the like.

Next, the operation of this embodiment will be described. The drum 10 is rotated in the Y direction at a constant peripheral speed (rotation speed) by the main motor 93. When one print medium M is fed by, for example, the cassette feeding means 71 selected by using the feed switching means 81 forming the feeding means 60, the leading end Mf of the printing medium M is supplied to both feeding rollers of the medium feeding means 90. 9
The posture is corrected by colliding with the first and second contact portions 99. The flexure of the print medium M in the flexure space SP facilitates its correcting ability.

Supply roller rotation drive control means (250)
When the posture correction due to the collision is completed and the printing medium M can be supplied to the drum 10 without skewing, the application of the supply rotational power is permitted. That is, the leading end Mf of the print medium M is engaged with both the supply rollers 91 and 92, and the print medium M enters a standby state. Then, the drive stop state switching means 84 operates, and the feeding means 60 is stopped.

After that, when the rotation position of the drum 10 detected by the position detection means 100 reaches the set position, the supply timing adjustment control means (250) drives the medium supply means 90 (91, 92). The printing medium M is supplied to the drum 10 side. That is, the print medium M is supplied at a speed corresponding to the peripheral speed of the drum 10.

Then, the negative pressure suction holding means 21 uses the negative pressure in the drum 10 established by the negative pressure establishing means 31 to suction hold the printing medium M. At the same time, the clamping claw holding means 41 (45, 43) acts as an auxiliary, and the clamping claw 4
2. A part (front end side) of the print medium M is applied to the drum 10 (11)
To be pinched. Further, the charging means 51 charges the print medium M. Prior to this, the preheating means (130) forcibly preheats and dries the print medium M, so that the charging can be performed efficiently. Therefore, the printing medium M can be securely held at the predetermined position in the Y direction on the outer peripheral surface 11 of the drum by suction.

Since the leading end side of the print medium M is held by the negative pressure suction before being held by the holding claws 141, the holding can be performed stably. Further, both supply rollers 9
If the nip pressure of 1,92 is released, the accuracy of the holding position on the drum 10 can be improved.

The control unit 250 includes the nozzle units 200C, 200M, 200Y, and 200B for each color (the nozzle unit elements 205A, 205B, 205C, and 205B).
D) to drive and control the respective divided rows S1 and S1 shown in FIG.
Dots D1, D in the first row (L1) in 2, 2, S4
5, D9,... Are printed simultaneously. Since the ink jet nozzles 207a to 207n for each color are arranged at the same position in the row (X1), the same dot (D1) for each color is used.
Color overlay can be performed accurately.

The unit moving means 110 moves the nozzle units 200C, 200M, 200Y, and 200B for each color forward in the X1 direction shown in FIG. At this time, a forward movement is performed at a constant speed while moving from the front dot D1 to the rear dot D2. Here, the control unit 250 controls the driving of each inkjet nozzle 207 using the high-speed rotational movement in the Y direction during this period, and controls the row (F) to which the previous dot D1 belongs.
Each dot (~ D1n-1, D1n) of 1) is
Is printed while rotating once. Each nozzle unit element 205 prints simultaneously.

Therefore, when the drum 10 makes one rotation,
Color printing of each dot (〜D1n-1, Dn) belonging to the column (F1) on the virtual locus R1 shown in FIG. 1 can be performed. Hereinafter, similarly, while moving from the front dot D2 to the rear dot D3, the dots (の D2n−1, D2n) of the column F2 to which the front dot D2 belongs are simultaneously printed on the virtual trajectory R2. That is, the inkjet nozzle 207
While moving a in the X1 direction by a predetermined pitch PT, the plane [(L1, L2 to Ln) ×
(F1, F2,..., F4)], the A4 size can be printed in multicolor in 2 seconds while simultaneously proceeding. Even if two rotations (1 sec) assigned to the attachment / detachment of the print medium M are added, the time is 3 seconds or less.

If the amount of movement of the nozzle unit 200 for each color in the X direction and the number of rotations N of the drum 10 are selected, the pitch of the inkjet nozzle 207 (P
T, PTp), color printing can be performed at a desired resolution. Further, a predetermined reference pitch PTp (= 1 /
Coarse pitch PT (= 300 inches) multiplied by N (= 4)
Using 1/75 inch, color printing with a resolution (300 dpi) corresponding to the reference pitch PTp can be performed.

In FIGS. 1 and 4, the last line (Ln) on the rear end side belonging to the same column (F1) as the first line (L1) dot D1 on the leading end side of the print medium M in the first column (F1). Although the position is shifted from the eye dot Dn by one dot in the X1 direction,
Since the displacement is 1/300 inch corresponding to the resolution (300 dpi), it cannot be visually recognized at all.

Furthermore, if the amount of reciprocating movement in the X1 direction is kept constant, and control is performed so that the dot D2 is reached when the drum 10 returns to the first row (L1) after one rotation, the first
The amount of positional displacement in the X1 direction between the first row (L1) dot D1 on the leading end side of the print medium M in the column (F1) and the last row (Ln) dot Dn on the trailing end side belonging to the same column (F1) is calculated. It can be smaller than one dot.

The ink on the printing medium M by the color printing is accelerated by the relative flow with the ambient air due to the high-speed rotation of the drum 10 (the printing medium M). High quality printing can be maintained because drying is accelerated quickly.

After printing one sheet, the unit moving means 110
Synchronizes the nozzle units 200 for each color and X
It is moved backward by a predetermined pitch PT in two directions. Prepare for the next print.

At the same time, the removal timing adjustment control means (250) controls the charge removal means 55 at a predetermined timing.
And the medium holding means 2
The holding force of 0 (21, 41) is eliminated and the medium peeling means 140 is operated. That is, the peeling claw 141 peels the printing medium M from the drum 10 (11), and after peeling, the printing medium M is used as a medium delivery means when the medium discharging / conveying means 16 disposed above the nozzle unit 200 for each color.
Deliver to the 0 side.

The medium discharging and conveying means 160 discharges and conveys the print medium M at a speed corresponding to its peripheral speed until the end of the printing medium M is separated from the drum 10 (11), and after the separation, the natural drying time can be lengthened. Switch to low speed. Then, the print surface side of the print medium M discharged and conveyed is forcibly dried by the ink drying means 181 provided at the end thereof.
Thereafter, by switching the direction switching means 190, the sheet can be quickly discharged to the discharge tray 192 or the upper discharge tray 193. Even if the hand touches the discharged print medium M, ink bleeding or the like does not occur.

At the end of the printing operation, the forward / backward moving means 220
Moves the nozzle unit 200 for each color, and operates the tube opening / closing means 218 with the ink return tube closed to increase the pressure in the ink buffer 206 and forcibly jet ink from each ink jet nozzle 207 to perform cleaning. The waste ink is collected by the waste ink collecting means 230. Thereafter, each ink jet nozzle 207 is covered with the cap 246 raised by the cap lifting / lowering means 240 to prevent drying.

According to this embodiment, the drum 10 rotatable at a constant peripheral speed, the medium supply means 290 for supplying the print medium M to the drum 10, and the negative pressure An establishing means 30 and a nozzle unit 200 for each color which is displaced in the rotational direction of the drum 10 and has a plurality of ink jet nozzles 207 are provided respectively. The print medium M supplied from the medium supply means 90 is formed on the outer peripheral surface 11 of the drum 10 so as to be capable of being held by suction, and the nozzle unit 200 for each color is selected for the print medium M rotating and moving together with the drum 10. Dramatically accelerated multi-color printing because it is formed so that color printing can be performed while spraying ink from each inkjet nozzle 207. And large number (e.g., 500 sheets) can achieve continuous printing operation of the.

A corresponding suction port 34 provided on the end face (5R) of the drum 10 and fixedly provided corresponding to the suction port 102 communicating with the internal space (10E) of the drum 10 includes: Since it is formed from the corresponding suction port 34 and the suction fan 32 that sucks air to make the inside of the drum into a negative pressure through the duct 35 through the duct 35, the structure can be simplified and realized at low cost.

Further, the holding claw holding means 4 as an auxiliary means
1 is provided so that the peripheral portion of the printing medium M, which has been negatively attracted and held by the negative pressure attracting and holding means 21 (31, 32, etc.), can be pressed and held on the outer peripheral surface 11 of the drum. Assures a stable and stable holding.

Since the holding claw holding means 20 (41) performs the holding and the holding release by the holding claw 42 while utilizing the rotation of the drum 10, the mechanism (43, 44) attached to the drum 10 is used. ) Is reduced and the rotational load can be reduced.

A charging means 51 and a replenishing charging means 53 are provided as auxiliary means to hold the printing medium M on the drum 10 by utilizing a charge attracting force, and a charge removing means 55 and a mechanical medium peeling means are provided. Since the print medium M is formed by separating the print medium M from the drum 10 by providing the print medium M, the print medium M can be more stably and reliably held on the drum 10 and can be smoothly separated from the drum 10. Therefore, continuous and high-speed color printing can be performed more stably.

The charging means 51 and the replenishing charging means 5
3. Since the charge removing means 55 and the medium peeling means 140 are arranged in this order from the upstream side in the rotation (Y) direction of the drum 10 to the downstream side, from the holding on the drum to the peeling after printing. The required number of rotations of the printing medium M can be minimized. Therefore, the printing speed can be further increased from this point.

The medium supply means 90 is provided with a pair of rollers 9.
The print medium M is formed so that the print medium M can be supplied to the drum 10 without skew after the leading end Mf of the print medium M collides with the contact portions 99 of the first and the second 92 and the posture thereof is corrected. 10 can be held accurately.

Further, when the rotational position of the drum 10 detected by the position detecting means 100 reaches a preset position, the print medium M is supplied to the drum 10 side. M can be accurately held by the drum 10.

Further, since the printing in the row (X) direction by the synchronous movement of each nozzle unit element 205 and the printing in the column (Y) direction using the high-speed rotation of the print medium M can proceed simultaneously, the printing can be further promoted. Print speed.

The pitch P between each ink jet nozzle is
T is set to N times the reference pitch PTp required to obtain a predetermined resolution, and the nozzle unit 200 for each color is moved in the direction of the drum axis (X) per rotation of the drum 10 to the reference pitch PTp.
The nozzle unit 200 for each color is formed so as to be movable only by N rotations of the drum 10 so that color printing at a predetermined resolution can be performed. Depending on the combination, they can be formed integrally or integrally over the entire length in the X direction.

Since the reciprocating movement amount of the nozzle unit 200 for each color in the X direction is, for example, 1/600 (= 4 dots) of the entire width (for example, 2400 dots),
It is possible to reliably wipe out the most important factor that hinders the high-speed printing in the X direction.

The ink jet nozzle 207 for each color is used.
Are arranged on the normal line to the drum 10,
The shape and size of the sprayed ink on the print medium M can be made uniform. Therefore, higher quality printing can be performed.

Further, the nozzle unit 200 for each color can be moved by 1 / N of the pitch PT between the ink jet nozzles while the drum 10 makes one rotation by the unit moving means 110. Since it is formed so that color printing can be performed at a resolution N times the resolution determined by the pitch PT, one of the drums 10 can be printed.
If the amount of movement per rotation (PT × 1 / N) and the number of rotations of the drum (N) during the movement are switched, color printing can be performed with the resolution switched while keeping the pitch PT between the ink jet nozzles constant.

In addition, since the corresponding ink jet nozzles 207 in each color nozzle unit 200 are arranged at the same position in the direction of the drum axis (X), higher quality printing can be performed from this point as well.

Further, a plurality (four) of nozzle unit elements 20 in which each color nozzle unit 200 is arranged in the direction of the drum axis (X) and displaced in the direction of rotation of the drum.
Since it is formed from 5A to 205D, it is easily available technically and cost-effectively.

Each of the nozzle unit elements 205A-2
05D is arranged in a zigzag manner with the other nozzle unit elements 205 adjacent in the drum axis direction in the drum rotation direction, so that the arrangement space can be minimized and the speed in the X direction is further increased by reducing the weight. , The color printing speed can be further increased.

Further, since the drive source of the unit moving means 110 is formed of one motor unit 121 having a reciprocating rod 122 capable of switching between in and out, the reciprocating movement of the nozzle unit 200 for each color in the X direction can be quietly performed. Can be performed smoothly and quickly. Therefore, higher quality and higher printing speed can be achieved. Switch to high speed and go forward (X
2), the printing speed can be further increased.

Further, the feeding means 60 is formed of a manual feeding means 61, a cassette feeding means 71, and a feeding switching means 81, and the fed printing medium M has a posture correcting function. Since the paper can be supplied to the drum 10 side via the supply means (supply roller unit) 90, the applicability to the change (switching) of the print target medium (M) is wide and easy to handle, and the printing speed is increased. In addition, high-speed color printing of, for example, 500 sheets can be continuously performed.

Further, since the ink drying means 130 is provided to positively dry the ink on the printing medium M held on the drum 10, the printing speed and the printing quality can be further improved. .

Further, since the printing surface side of the print medium M that has been peeled off and conveyed while being discharged from the drum 10 is formed to be forcibly dried by the ink drying means 181, the discharged print medium M is immediately touched. Even if ink does not bleed or mix. Therefore, also from this point, the speeding up of printing can be further promoted and handling is further facilitated.

Further, since the medium discharge / convey means 160 is formed such that the print medium M separated from the drum 10 using the medium separation means 140 can be discharged and conveyed at a speed corresponding to the peripheral speed of the drum 10, Continuous color high-speed printing can be promoted.

Further, since the medium discharging / conveying means 160 is formed by the belt conveyor 161 in contact with the non-printing surface of the printing medium M and the medium pressing means (171) capable of contacting the printing surface, the printing medium M after printing is printed. Can be more stably and smoothly discharged and conveyed. The medium delivery means (141) further promotes this.

Further, a direction switching means 190 is provided downstream of the medium discharge / conveyance means 160 so that the print medium M can be selectively switched to one of two directions so as to be discharged.
The printing medium M after printing can be handled more easily.

Further, since the ink tanks 213 for each color are arranged at positions away from the nozzle unit 200 for each color, the capacity of the ink tank 213 can be increased. Therefore, since a complicated replacement interval of the ink tank 213 can be lengthened, continuous color printing can be performed for a long time, and the reciprocating movement in the X direction can be further accelerated by reducing the load on the nozzle unit 200 for each color.

The ink supply means 210 connects the nozzle units 200 for each color and the ink tanks 213 for each color with the ink supply tube 215, and is formed so that the pressure of each color ink can be equalized by the urging means 216. Therefore, the degree of freedom in layout can be greatly expanded, and higher quality printing can be performed.

Further, each ink jet nozzle 207 of each color nozzle unit 200 can be separated and approached to the drum 10 by the reciprocating means 220 and is covered by the cap 246 raised by the cap elevating means 240 in the separated state. This prevents the ink from drying out of the nozzles.

[0157]

According to the first aspect of the present invention, a drum rotatable at a constant peripheral speed, a medium supply means and a nozzle unit for each color having a large number of ink jet nozzles are provided, and a suction hole penetrating through the inside and outside of the drum is provided. The print medium supplied from the medium supply means is formed so as to be able to be sucked and held on the outer peripheral surface of the drum by using the negative pressure in the drum via the negative pressure in the drum. Since it is formed so that color printing can be performed while spraying ink from the inkjet nozzles, multicolor printing can be performed at high speed, and a continuous printing operation of many sheets is possible.

Further, according to the second aspect of the present invention, the negative pressure establishing means is provided on the end face of the drum and fixedly disposed corresponding to the suction port communicating with the internal space of the drum. Since it is formed of a suction fan that sucks air in order to make the inside of the drum a negative pressure from the corresponding suction port, the same effect as that of the invention of claim 1 can be obtained, and further, the structure is simple and the cost is low. Can be embodied.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining a technical basis of the present invention and a printing operation of an embodiment.

FIG. 2 is an overall configuration diagram showing an embodiment of the present invention.

FIG. 3 is a schematic diagram for explaining a relationship between a drum and a nozzle unit.

FIG. 4 is also a view for explaining a nozzle unit.

FIG. 5 is also a view for explaining a feeding means.

FIG. 6 is a view for explaining a negative pressure suction holding unit.

FIG. 7 is a view for explaining a holding claw holding means and a holding operation.

FIG. 8 is a view for explaining a holding claw holding means and a holding release operation.

FIG. 9 is also a view for explaining a unit moving means.

FIG. 10 is also a view for explaining a medium discharge / convey means.

FIG. 11 is a diagram for explaining an ink supply unit.

FIG. 12 is a view for explaining an urging means.

FIG. 13 is a front view for explaining a cap elevating means.

FIG. 14 is a side view for explaining the cap elevating means.

FIG. 15 is a diagram for explaining a conventional example (1).

FIG. 16 is a diagram for explaining a conventional example (2).

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Main body case 10 Drum 10E Hollow part (space in a drum) 11 Outer peripheral surface 12 Suction hole 14 Suction port 20 Medium holding means 21 Negative pressure suction holding means 31 Negative pressure establishing means 32 Suction fan 34 Corresponding suction port 35 Duct 41 Holding claws Means 51 Charging means 53 Replenishing charging means 55 Charge removing means 60 Feeding means 61 Manual feeding means 71 Cassette feeding means 81 Feed switching means 90 Medium feeding means 100 Position detecting means 110 Unit moving means 111 Reciprocating mechanism 130 Ink drying means (preheating means) 140 Medium peeling means 160 Medium discharging / conveying means 181 Ink drying means 190 Direction switching means 200 Nozzle unit for each color 205 Nozzle unit element 207 Inkjet nozzle 210 Ink supply means 216 Urging means 218 Pressure adjusting means 220 Progress Moving means 230 waste ink recovery unit 240 cap elevating means 250 control unit M print medium

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Hitoshi Shioki 6-78 Minami-cho, Mishima-shi, Shizuoka Pref.

Claims (2)

[Claims] 1. A drum rotatable at a constant peripheral speed, a medium supply means for supplying a printing medium to the drum, a negative pressure establishing means for making a negative pressure inside the drum, and a positional shift in a rotational direction of the drum. And a nozzle unit for each color having a large number of ink jet nozzles respectively. The print medium supplied from the medium supply means through a suction hole penetrating the inside and outside of the drum and utilizing the negative pressure in the drum is provided on the outer periphery of the drum. An ink-jet printing apparatus characterized by being formed so as to be capable of holding by suction on a surface and performing color printing while spraying ink from a selected ink-jet nozzle of a nozzle unit for each color onto a printing medium rotating and moving together with a drum. Printer. 2. A corresponding suction port provided on an end face of the drum and fixedly disposed corresponding to a suction port communicating with a space inside the drum, and a negative pressure establishing means for moving the inside of the drum from the corresponding suction port. 2. An ink jet printer according to claim 1, wherein said ink jet printer is formed of a suction fan for sucking air to make a negative pressure.