JPH0811382A - Thermal transfer serial video printer - Google Patents

Abstract

PURPOSE:To print a full size image or a half-size image selectively with both production costs and running costs kept low. CONSTITUTION:In a full-size print mode, a frame memory is read out vertically, and the moving distance of a head carriage per picture element in the scanning direction is made L2. In a half-size print mode, image data from of the frame memory is read out horizontally, and the moving distance of the head carriage per picture element in the sub-scanning direction is made L3 (L3<L2).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermal transfer serial video printer, and more particularly to a full-size print for printing a bordered image on almost the entire surface of a recording sheet and a post card type in which the image is recorded on almost half of the recording sheet. The present invention relates to a thermal transfer serial video printer which performs half size printing.

[0002]

2. Description of the Related Art A video image signal output from a video recorder such as a video tape recorder or an electronic still camera is digitized and taken into a frame memory, and this image data is subjected to image processing such as masking processing and then printed out. Printers are known. As for this print mode, in addition to the full-size mode (normal mode) in which one frame of a video image is printed on almost all the screen of A6 size recording paper at an aspect ratio of approximately 3: 4, the image is vertically and horizontally converted and pixel There is a two-screen multi-mode in which thinning processing is performed to record two identical half-size images on the upper and lower sides of a recording sheet.

On the other hand, there are some commercially available word processors that can capture an image using a hand scanner or the like, process the image, and record it on a postcard or the like. Many of these word processors use a thermal head in which a plurality of heating elements are arranged in the main scanning direction in order to reduce the size and weight of the device, and the thermal head is moved in the sub scanning direction together with the ink ribbon cassette. The thermal transfer serial printer that transfers the ink of (1) to recording paper to record one line, and then feeds the paper in the main scanning direction to record the next one line is installed.

[0004]

In any of the print forms output from the above video printers, an image is recorded on almost the entire surface of the recording paper, and there is almost no margin portion. Therefore, when used as a post card. Or, it was inconvenient when writing characters such as titles and comments. In addition, a video printer capable of vertical / horizontal conversion of an image transfers the video image signal from the frame memory to another data expansion memory for thinning processing and vertical / horizontal conversion processing. An arithmetic unit for performing the vertical / horizontal conversion processing is required, and the cost is high.

Further, the word processor as described above has a drawback that the ink ribbon is uneconomical in addition to the drawback that the video image signal cannot be taken in and the image processing takes time. This is because the standard recording paper used in many word processors is A4 size, and the length of the ink ribbon sent when recording one line is constant according to the width of A4 size recording paper. This is because, when an image is recorded on a postcard of almost A6 size, many parts of the ink ribbon are idly fed in an unused state.

The present invention is capable of selectively printing a half-size image and a full-size image, and
An object of the present invention is to provide a low-cost thermal transfer serial video printer that does not require a data expansion memory or a computing unit, eliminates waste of an ink ribbon, and reduces both manufacturing cost and running cost.

[0007]

In order to achieve the above object, the thermal transfer serial video printer of the present invention intermittently moves one line at a time in the main scanning direction with the recording paper being vertically long, and the thermal head and the ink. In a thermal transfer serial video printer that records an image line by line while moving a head carriage that holds a ribbon in the sub-scanning direction, the thermal transfer serial video printer includes M pixels in the horizontal direction and N pixels (M> N) in the vertical direction. Frame memory for storing images, a full-size print mode for printing a full-size image with a large border size on almost the entire surface of the recording paper, and a half-size image recording paper having a half size of the full-size image. Half-size print mode that prints almost half of the When the size print mode is designated, the frame memory is read out from the vertical direction, when the half size print mode is designated, the frame memory reading means for reading out the frame memory in the horizontal direction, and when the full size print mode is designated, In order to change the length of the pixel in the sub-scanning direction by increasing the moving distance of the head carriage per pixel and reducing the moving distance of the head carriage per pixel when the half size print mode is designated. Pixel length control means is provided.

Further, the pixel length control means may change the moving speed of the thermal head while keeping the recording time per pixel constant, and the moving speed of the thermal head is kept constant. The recording time per pixel may be changed.

[0009]

In the full-size print mode, the frame memory is read out in the vertical direction and the moving distance per pixel of the head carriage is increased.
A full-size image with a large border is printed on almost the entire surface of the recording paper. Further, in the half-size print mode, the frame memory is read out in the horizontal direction and the moving distance per pixel of the head carriage is shortened, so that a half-size image having almost half the size of the full-size image is almost printed on the recording paper. Printed in half.

[0010]

2 shows a thermal transfer serial video printer according to the present invention, a paper feed port 11 is formed in the upper portion of a box-shaped printer body 10, and a recording paper 12 of A6 size (postcard size) is made vertically long. Is inserted. The recording sheet 12 is nipped by a pair of feed rollers 13 and 14 and is intermittently fed line by line in the main scanning direction indicated by the arrow.

A color ink ribbon cassette 16 is set on the head carriage 15. As is well known, the color ink ribbon cassette 16 is provided with two reels, and the color ink ribbon 17 is wound around with both ends fixed. The head carriage 15 includes a thermal head 22, a mark sensor 23, reel shafts 24 and 2.
And 5 are provided. When the color ink ribbon cassette 16 is set, the thermal head 22 has notches 18,
Go into one of the nineteen. The mark sensor 23 enters a notch (not shown) formed in the front corner of the color ink ribbon cassette 16.

The reel shafts 24 and 25 are fitted on the reel hubs of the color ink ribbon cassette 16. One reel shaft 24 is used for the pulse motor 2 in the head carriage 15.
7 (see FIG. 3), the color ink ribbon 17 is wound up by a length corresponding to one ink dot during printing.

The head carriage 15 is inserted into a guide rod 28 and is slidably supported by a guide rail 29. A part of the timing belt 30 is fixed to the head carriage 15. The timing belt 30 is wound around pulleys 31 and 32. One pulley 31 is connected to the pulse motor 33. The platen 34 is arranged to receive the back of the recording paper 12.

The printer body 10 is provided with a print mode switching button 35, a print button 36 for instructing the start of printing, and a display 37. Each time the print mode switch button 35 is pressed, it switches between the full size print mode (standard mode) and the half size print mode (postcard mode). In the full-size print mode, a full-size image with an edge ratio of 3: 4 is printed on almost the entire surface of the recording paper 12. In the half-size print mode, a greeting text can be written below the recording paper 12,
A half-size image of half the full-size image and an aspect ratio of about 3: 4 is recorded on almost the upper half of the recording paper 12. Further, the display 37 displays the print mode switching button 3
In addition to displaying the type of print mode set by 5, for example, characters of "full size print mode" and "half size print mode", it is used for displaying warnings of operating procedures and various troubles.

In FIG. 3, an NTSC video signal of a video image captured by an electronic still camera, a video camera or the like is input from an input terminal 40. The video signal for one screen input from the input terminal 40 is input to the decoder 41, where it is separated into a red signal, a green signal and a blue signal. These color signals are digitized by the A / D converter 42 and converted into blue image data, green image data, and red image data, which are sent to the frame memory unit 43. The frame memory unit 43 includes a blue frame memory 43a, a green frame memory 43b, and a red frame memory 43c. The system controller 45 causes the blue image data, the green image data, and the red image data to correspond to the corresponding frame memories 43a to 43a. 43c.

When the print button 36 is pressed, the system controller 45 sequentially reads out the image data for each line from the frame memories 43a to 43c through the reading circuit 48 and sends the image data to the data conversion unit 46. At the time of this reading, the image data is read in the reading direction according to the print mode set by the print mode switching button 35. The reading of this image data will be described later.

The blue image data for one row read from the blue frame memory 43a is sent to the data conversion section 46 and converted into yellow image data, and then sent to the head driver 47. The head driver 47 drives the thermal head 22, and, for example, 24 heating elements 22 a, 2
2b, ... (See FIG. 1) are selectively driven. The heating elements 22a, 22b, ... Are arranged in a line in the main scanning direction, and heat and press the color ink ribbon 17 from the rear side, so that the head carriage 15 moves to the left end in the drawing of FIG. While moving from the initial position to the right (sub scanning direction), the softened or melted yellow ink is transferred to the recording paper 12.

After one line of yellow image is recorded in this way, the head carriage 15 is returned to the initial position, and one line of green image data is read from the green frame memory 43b to form magenta image data. The magenta ink is converted and transferred to the recording paper 12. Thereafter, similarly, one row of red image data is read from the red frame memory 43c, converted into cyan image data, and cyan ink is transferred onto the recording paper 12. With such a three-color sequential recording, a full-color image is recorded line by line.

The system controller 45 controls the driving of the pulse motors 27, 33 and 48. The pulse motor 48 rotates the feed rollers 13 and 14 to feed the recording paper 12 in the main scanning direction.

As shown in FIG. 4, the color ink ribbon 1
7, a yellow ink area 51, a magenta ink area 52, and a cyan ink area 53 are arranged in the order of thermal recording. Each of the ink areas 51 to 53 has a length of L1 and is the same as the moving distance of the head carriage 15 in the sub-scanning direction. Further, two marks 54 with black lines are recorded in front of the yellow ink area 51, and a mark 55 with one black line is recorded in front of the magenta ink area 52 and the cyan ink area 53. These marks 54 and 55 are detected by the mark sensor 23, and the cue of the ink area and its type are identified.

The reading of image data will be described by taking the blue frame memory 43a as an example. In FIG. 5 showing the memory area 44 of the blue frame memory 43a, the number of pixels for one screen becomes M pixels in the horizontal direction and N pixels in the vertical direction by sampling the NTSC video signal at, for example, 14 MHZ. The aspect ratio is approximately 6: 7.

In the full size print mode, one row of blue image data is read out vertically from the memory area 44, and in the half size print mode, blue image data is read out horizontally. In this embodiment, the number of heating elements of the thermal head 22 is, for example, 24, so that the number of pixels included in one row is 24 pixels × 240 pixels (area indicated by reference numeral 44a) in the full size print mode, and the half size print mode. 24 pixels x 384 pixels (reference numeral 44b
Area).

In FIG. 1A showing the recording state in the full size print mode, each heating element of the thermal head 22 has a length A in the main scanning direction and a length B in the sub scanning direction.
It has a rectangular shape. For example, A is 282 μm and B is 1
It is 00 μm. When printing, the thermal head 22
Is moved by a unit movement distance L2 (for example, 33 μm) in the sub-scanning direction, and each heating element has one pixel 57, for example, 8 pixels.
Record in gradation. For example, at the gradation level “4”, ink dots 5 of 282 μm × 199 μm as shown by the diagonal lines are formed.
8 is transferred into the pixel 57.

The pixel 57 has a length A in the main scanning direction of 282.
μm, and the length C in the sub-scanning direction is 331 μm, which is a rectangular shape, and A: C = 6: 7. Since this ratio is the same as the aspect ratio of the sampling points (original pixels) of the image data, the image is recorded without distortion, and the print result as shown in FIG. 6 is obtained. The print image 60 is recorded on the recording paper 12 in 16 lines (384/24), and L4 × L
It comes in size 5. This L4 is about 108 mm (282μ
m × 384 pixels), L5 is about 79 mm (331 μ
m × 240 pixels), L5: L4≈79: 10
8≈3: 4.

In FIG. 1B showing the recording state in the half size print mode, the system controller 45
Changes the moving speed of the head carriage 15 while keeping the recording time per pixel constant, and sets the unit moving distance of the thermal head 22 to L3, which is shorter than L2. For example, if L3 is about 20.3 μm, the length D of the pixel 61 in the sub-scanning direction is 242 μm, so A: D = 7: 6. It should be noted that, for example, at the gradation level “4”, the ink dots 62 of 282 μm × 160.9 μm as shown by hatching are transferred to the pixels 61.

Since the aspect ratio 7: 6 of the pixel 61 is the same as the aspect ratio of the sampling point (original pixel) of the image data, the image is recorded without distortion and a print result as shown in FIG. 7 is obtained. This print image 65 is recorded on the recording paper 12 in 10 lines (240/24), and L6 × L
7 size. This L6 is about 68 mm (282 μm
× 240 pixels), L7 is about 93 mm (242 μm)
(× 384 pixels), L6: L7≈68: 93≈
It will be 3: 4. The other frame memories 43b, 43
Since the same applies to c, the description is omitted.

Next, the operation of the above embodiment will be described. For example, a video signal of a video image reproduced by a still video player is converted into blue image data, green image data, and red image data via a decoder 41 and an A / D converter 42, and then sent to a frame memory unit 43. The
It is written in each of the frame memories 43a to 43c. At the time of this writing, the system controller 45 specifies the memory address.

The print mode switching button 35 is pressed to select, for example, the full size print mode. After confirming that the display 37 is set to the full size print mode, the print button 36 is pressed. The system controller 45 drives the pulse motor 48,
The feed rollers 13 and 14 are rotated. These feed rollers 13 and 14 nip the recording paper 12 vertically inserted from the paper feed port 11 and feed the recording paper 12 so that the first row (see FIG. 6) faces the thermal head 22.

The read circuit 48 is used for the blue frame memory 4
The first line of blue image data is read out from 3a in the vertical direction and sent to the data conversion unit 46. The data converter 46 converts this into yellow image data and then sends it to the thermal head 22 via the head driver 47.

The system controller 45 drives the pulse motor 27 to wind up the color ink ribbon 17,
The cue of the yellow ink area 51 is performed. This cueing is based on the time when the mark sensor 23 detects the mark 54 during the feeding of the color ink ribbon 17, and the color ink ribbon 17 is fed by the distance of the passage from the mark sensor 23 to the thermal head 22. Is done by doing.

After cueing the yellow ink area 51,
The thermal head 22 presses the back surface of the yellow ink area 51 against the recording paper 12, and the color ink ribbon 17 is wound up by the unit moving distance L2. At the same time, the timing belt 30 is rotated by the pulse motor 33, the head carriage 15 is moved by the unit moving distance L2, and the thermal head 22 records a yellow image.

When the recording of the yellow image on the first line is completed in this way, the head carriage 15 is returned to the beginning of the first line. At the same time, the color ink ribbon 17 is wound up, the mark 55 is detected, and the magenta ink area 52 is cued. Magenta ink area 52
After cueing, the head carriage 15 is moved while winding the color ink ribbon 17 by the unit moving distance L2. During this movement, the first line of green image data is read from the green frame memory 43b and converted into magenta image data. Then, based on this, the thermal head 22 is driven and a magenta image is recorded.
Thereafter, in the same manner, a cyan image is recorded using the cyan ink area 53 based on the first line of the cyan image data read from the red frame memory 43c and converted. In this way, a full-color image is recorded on the first line of the recording paper 12 by three-color sequential recording.

When the recording of the first line is completed, the system controller 45 drives the pulse motor 48 to rotate the pair of feed rollers 13 and 14 to feed the recording paper 12 for one line in the main scanning direction. Along with this, the head carriage 1
5 is returned to the leftmost initial position.

In the same manner as in the first line, the full-color image is recorded in three-color sequential recording on the second and subsequent lines. When the recording up to the 16th line is completed, the pulse motor 48 is continuously rotated and the recording is completed. The recording paper 12 is ejected. The recording paper 12 has a full-color image 60 with an edge having an aspect ratio of about 3: 4.
Is recorded on almost the entire surface.

When recording in the half size print mode, the print mode switching button 35 is pressed to set the half size print mode. The recording paper 12 is placed in the vertical position and inserted into the paper feed port 11 as in the full-size print mode. When you press the print button 36,
The first row (see FIG. 7) of the recording paper 12 faces the thermal head 22.

The system controller 45 corresponds to the half size print mode and the frame memories 43a to 4a.
The reading direction of each image data from 3c is changed from the vertical direction to the horizontal direction, the winding speed of the color ink ribbon 17 and the moving speed of the head carriage 15 are changed, and the data is sent within the same recording time as in the full size print mode. The unit moving distance of the color ink ribbon 17 and the unit moving distance of the head carriage 15 are changed from L2 to L3, respectively.

The blue image data for the first line is read out horizontally from the blue frame memory 43a by the reading circuit 48. The blue image data is converted into yellow image data by the data conversion unit 46 and sent to the thermal head 22 via the head driver 47.

After cueing the yellow ink area 51,
The thermal head 22 presses the back surface of the yellow ink area 51 against the recording paper 12, and the color ink ribbon 17 is wound up by the unit moving distance L3. At the same time, the timing belt 30 is rotated by the pulse motor 33, the head carriage 15 is moved by the unit movement distance L3, and the yellow image is recorded by the thermal head 22. Thereafter, similarly, a magenta image and a cyan image are recorded on the same line, and a full-color image is recorded on the first line by three-color sequential recording. Similarly, when the full-color image is recorded from the second line to the tenth line, the pulse motor 48 continuously rotates and the recording sheet 12 (see FIG. 7) on which recording has been completed is discharged. On the recording paper 12, a half-size image 65 having an aspect ratio of about 3: 4, which is about half the size of a full-color image, is recorded on the upper half. You can use it as a postcard by writing greetings in the space below.

Since the recording paper 12 is inserted in the same direction in both the full-size print mode and the half-size print mode, the print images 60 and 65 have substantially the same length in the sub-scanning direction. The same ink ribbon can be used, and the running cost can be kept low.

In the above-described embodiment, when the length of one pixel in the sub-scanning direction is changed in each print mode, the moving speed of the thermal head is changed while keeping the recording time per pixel constant. Although the total recording time changes, the recording time per pixel may be changed while keeping the moving speed of the thermal head constant. Further, in the half-size print mode, the print image is recorded on the upper half of the recording paper, but the paper feed amount at the start of printing may be changed and may be recorded on the lower half of the recording paper or in the middle.

[0041]

As described above, according to the thermal transfer serial video printer of the present invention, the reading direction of the image data from the frame memory is changed, and the thermal head and the ink per pixel are changed depending on the reading direction of the image data. Since the moving distance of the ribbon in the sub-scanning direction is changed, a full-size image and a half-size image for postcards can be selectively printed. In addition, since the data expansion memory and the arithmetic unit for performing the thinning-out process / vertical / horizontal conversion process are not required, the cost of the apparatus becomes low. In addition, since the recording paper feed direction is the same for both half-size print and full-size print,
The same ink ribbon can be used without waste, and the running cost can be reduced.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing pixels printed in a full size print mode and pixels printed in a half size print mode.

FIG. 2 is a perspective view of a thermal transfer serial video printer.

FIG. 3 is a block diagram showing an electrical configuration of a thermal transfer serial video printer.

FIG. 4 is an explanatory diagram of a color ink ribbon.

FIG. 5 is an explanatory diagram showing a memory area of a blue frame memory.

FIG. 6 is an explanatory diagram showing a print image recorded in a full size print mode.

FIG. 7 is an explanatory diagram showing a print image recorded in a half size print mode.

[Explanation of symbols]

12 Recording Paper 15 Head Carriage 16 Color Ink Ribbon Cassette 17 Color Ink Ribbon 22 Thermal Head 35 Print Mode Change Button 36 Print Button 43 Frame Memory 43a, 43b, 43c Frame Memory 43a ₀ Memory Area 45 System Controller 57, 61 Pixels 58, 62 Ink dot 60 Full size image 65 Half size image

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location B41M 5/26 H04N 5/76 E 5/91 7267-2H B41M 5/26 P H04N 5/91 H

Claims (3)

[Claims] 1. An image is moved line by line while intermittently moving one line at a time in the main scanning direction while the recording paper is vertically long and moving the head carriage holding the thermal head and the ink ribbon in the sub scanning direction. In a thermal transfer serial video printer for recording, a frame memory for storing an image composed of M pixels in the horizontal direction and N pixels (M> N) in the vertical direction, and a frame with a border is formed on almost the entire surface of the recording paper. Print mode designating means for selecting one of a full size print mode for printing a large full size image and a half size print mode for printing a half size image having a size of about half of the full size image on almost half of the recording paper; , When the full size print mode is specified, the frame memory is read from the vertical direction, When the half size print mode is designated, the frame memory reading means for reading out the frame memory in the horizontal direction, and when the full size print mode is designated, the moving distance per pixel of the head carriage is increased to make the half size print mode. When is specified, the moving distance per pixel of the head carriage is reduced,
A thermal transfer serial video printer provided with a pixel length control means for changing the length of the pixel in the sub-scanning direction. 2. The thermal transfer serial video printer according to claim 1, wherein the pixel length control means changes the moving speed of the thermal head while keeping the recording time per pixel constant. 3. The thermal transfer serial video printer according to claim 1, wherein the pixel length control means changes the recording time per pixel while keeping the moving speed of the thermal head constant.