JPH0561105B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a multicolor recording device that prints multiple colors on paper such as plain paper, and particularly relates to a multicolor recording device that prints colored toners of different colors onto the same transfer belt by energizing a plurality of thermal heads. The present invention relates to a multicolor recording device in which each colored toner is welded to a transfer belt and transferred onto a sheet of paper.

In recent years, with the spread of color CRTs (cathode rays), there has been a strong desire for multicolor recording devices, and wire dot type and inkjet type multicolor recording devices have already been developed to meet these demands. developed and put into practical use. However, multicolor recording devices using these methods
They have problems with printing speed and resolution, and do not have sufficient recording capacity to handle the increased amount of information currently available. Furthermore, electrophotographic multicolor recording devices that are different from these methods have already been put into practical use, but such electrophotographic multicolor recording devices have problems in terms of printing speed and resolution. Although this method is generally satisfactory, there are disadvantages in that the device itself is complicated and expensive.

In view of the above points, the present invention provides a multicolor recording device that can perform multicolor recording at sufficient printing speed and resolution, and can reduce the cost of the device itself. a transfer belt drive means for stretching and running the transfer belt; and a plurality of toners each arranged sequentially along the running direction of the transfer belt and supplying colored toners of different colors to one surface of the transfer belt. a supply mechanism, each of which is arranged opposite to each of the toner supply mechanisms with the transfer belt in between, and each of which is energized according to print data corresponding to the color of the colored toner supplied by the toner supply mechanism, so that the transfer belt and sequentially weld primary images of the colored toners in a shape corresponding to the print data to one surface of the transfer belt, forming a mixed primary image in which the primary images of the respective colored toners are superimposed. The apparatus is characterized by comprising a transfer head and a transfer head which heats the transfer belt and presses it against the printing paper to fix the mixed primary image formed on the transfer belt onto the printing paper.

An embodiment of the invention will be described with reference to the drawings.

First, prior to explaining the multicolor recording apparatus according to the present invention, a subtractive color mixing method, which is a multicolor printing method of this multicolor recording apparatus, will be explained. The subtractive color mixing method consists of creating a cyan image that absorbs only red light from white light, which includes light of all visible wavelengths, a magenta image that absorbs only edge-colored light, and a yellow image that absorbs only blue-violet light. Images of each color are obtained by using the images.

Therefore, by superimposing these cyan, magenta, and yellow images, the colors shown in FIG. 1 are obtained.

A multicolor recording apparatus according to the present invention to which the principle of the subtractive color mixing method described above is applied will be described below.

FIG. 2 is a sectional view showing an example of the configuration of a multicolor recording apparatus according to the present invention. In this figure, 1a~
Reference numeral 1d designates drive pulleys driven by stepping motors (not shown), and a transfer belt 2 is stretched around these drive pulleys 1a to 1d. The transfer belt 2 has good affinity for each colored toner (Y toner 6c, M toner 7c, C toner 8c) to be described later, and has high chemical resistance and heat resistance.
This transfer belt 2 is made of a thin resin film made of a material (for example, sodium-treated Teflon) that not only does not change its dimensions even with changes in heat and humidity, but also has excellent mechanical properties. As shown in FIG. 3, header marks 2a and 2b are provided. Further, thermal heads 3 to 5 are provided between the drive pulleys 1a and 1b so as to be in contact with the inner surface of the transfer belt 2. The thermal head 3 has a large number of heating elements, and generates heat when a yellow (Y) color signal is supplied, and this heat causes the Y toner 6c supplied by a toner supply mechanism 6a, which will be described later, to be transferred to the surface of the transfer belt 2. Y toner 6c is applied to the surface of the transfer belt 2.
The thermal heads 4 and 5 are configured to form a primary image having a shape corresponding to a color signal.Similarly, the thermal heads 4 and 5 generate heat when supplied with a magenta (M) color signal and a cyan (C) color signal, respectively. Color signal C
It is designed to form a primary image corresponding to a color signal. Further, below the thermal heads 3 to 5, colored toner supply mechanisms 6 to 8 are provided so as to be in contact with the outer surface of the transfer belt 2.
The colored toner supply mechanism 6 has a toner container 6a and an impeller 6b, and as the impeller 6b rotates, yellow toner (Y toner) 6c inside the toner container 6a is scooped up and supplied to the outer surface of the transfer belt 2. be done. Similarly, the colored toner supply mechanism 7 supplies magenta toner (M toner) 7c, and the colored toner supply mechanism 8 supplies cyan toner (C toner).
8c is supplied to the transfer belt 2. Also, between these colored toner supply mechanisms 6 and 7, there is a pressure roller 9a,
9b are arranged to face each other with the transfer belt 2 interposed therebetween. The pressure rollers 9a and 9b apply light pressure to prevent the primary image of Y toner 6c formed on the transfer belt 2 by the thermal head 3 from falling off the transfer belt 2, and also apply pressure to the primary image formed on the transfer belt 2 by using a light pressure. This heats the Y toner 6c.
Similarly, pressure rollers 10a, 10b and pressure rollers 11a, 11b are provided between the colored toner supply mechanisms 7 and 8, and between the colored toner supply mechanism 8 and the drive roller 1b, respectively. Each toner 6c, 7 formed by ~5
Each of the primary images formed by images 8c and 8c is pressurized and heated. Through pressure and heating in this manner, a mixed primary image consisting of primary images of each toner color is formed on the surface of the transfer belt 2. Furthermore, optical detectors 12 to 14 (for example, photo interrupters) for detecting the header marks 2a and 2b are provided upstream of each of the thermal heads 3 to 5 (on the right side in the figure), and each thermal head head 3
-5 heat generation timing is controlled. Further, the transfer head 1 is arranged between the driving pulleys 1b and 1c so as to be in contact with the inner surface of the transfer belt 2.
5 is provided, and the mixed primary image on the transfer belt 2 is
The image is transferred onto plain paper 17 by this transfer head 15 and a transfer roller 16 provided opposite to this transfer head 15 . In this case, similarly to each of the thermal heads 3 to 5, the transfer head 15
is the upstream side of the transfer head 15 (lower side in the figure)
The timing of the heat generation is controlled by an optical detector 18 provided at the. In addition, the drive pulley 1
Cleaners 19a and 19b are disposed facing each other between a and 1d with the transfer belt 2 in between, and the cleaners 19a and 19b clean the transfer belt 2 and remove toner remaining on the transfer belt 2. It's summery.

Next, the operation of this embodiment with the above configuration will be explained in the fourth section.
This will be explained with reference to the waveform diagram shown in the figure. first,
Pulleys 1a to 1 driven by stepping motors
When d is driven, the transfer belt 2 is thereby driven in the direction of arrow A. Then, when the optical detector 12 detects the header mark 2a (or 2b) at time t1 shown in FIG. 4A, this time t
1, the thermal head 3 is driven after a period T delay (see FIG. 4B), and the Y toner 6c is deposited on the transfer belt 2.
are welded, and a yellow primary image (Y primary image) is sequentially formed according to the dot display method. Next, this Y primary image is sent to the magenta (M) image section 4a by the movement of the transfer belt 2. and the next optical detector 13
However, for example, when the header mark 2a is detected at time t2 shown in FIG. An M primary image is formed by the M toner 7c. Next, the mixed primary image (Y/M primary image) of these Y primary image and M primary image is processed by the next C primary image section 5a,
Further, it is mixed with a C primary image to form a Y/M/C mixed primary image and sent to the transfer section 15a. When the optical detector 18 detects the header mark 2a, the transfer head 15 is energized and heated, and the Y/M/C mixed primary image on the transfer belt 2 is transferred onto plain paper 17, which has higher affinity. Further, in this case, since the plain paper 17 is heated by the transfer section 15a, the transferred Y/M/C mixed primary image is instantly fixed. The plain paper 17 is sent out as the transfer belt 2 moves, and the colored toner (residual mixed primary image) remaining on the transfer belt 2 is cleaned by cleaners 19a and 19b. Thereafter, the above-described operations are repeated in the same manner, and two sheets of plain paper 17 are printed each time the transfer belt 2 rotates once.

Note that in the embodiment described above, the pressure roller 9
a to 11b are used to prevent the colored toner welded by the thermal heads 3 to 5 from falling off the transfer belt 2. However, by improving the material of the transfer belt 2 and the physical properties of the colored toner, these effects can be prevented. It is also possible to eliminate the pressure rollers 9a to 11b and simplify the device.

Further, in the embodiment described above, the optical detectors 12 to 14 and 18 are used to detect the header marks 2a and 2b on the transfer belt 2, but these header marks 2a and 2b are not detected by, for example, marking or punching. The detector may be formed of a hole, a metal piece, or the like, and in this case, the detector may be selected depending on the type of header mark used.

Furthermore, in the embodiment described above, the length of the transfer belt 2 is twice the length _l1 of the printing area E (see FIG. 5) of the plain paper 17; Of course, it is also possible to make it an integral multiple of ₁ .

As described above, the multicolor recording apparatus according to the present invention includes a transfer belt, a transfer belt drive means for stretching and running the transfer belt, and each of the transfer belts is arranged in sequence along the running direction of the transfer belt, and a plurality of toner supply mechanisms that supply colored toners of different colors to one side of the transfer belt;
Each of them is arranged opposite to each of the toner supply mechanisms with the transfer belt in between, and each of the toner supply mechanisms heats the transfer belt by being energized according to print data corresponding to the color of the colored toner supplied by the toner supply mechanism; a plurality of thermal heads for sequentially welding primary images of a shape corresponding to the printing data made of the colored toners onto one surface of the transfer belt, and forming a mixed primary image in which the primary images made of the respective colored toners are superimposed; Since it has a transfer belt that heats the transfer belt and presses it against the printing paper to fix the mixed primary image formed on the transfer belt to the printing paper, printing on the paper can be performed in one printing process. Unlike general multicolor recording devices, there is no need to rotate or reciprocate a pre-cut sheet several times during printing, so multicolor recording can be performed at sufficient printing speed and resolution. Furthermore, in this invention, paper can be printed using an inexpensively available thermal head and colored toner, which is a simple material, so the maintainability of the entire device can be improved and the price of the device can be reduced. be able to. Further, according to the present invention, it is possible to perform printing of higher quality than a so-called direct transfer type device. That is, a direct transfer type multicolor recording device that directly transfers each color toner onto printing paper has a drawback that the adhesion state of each color toner varies depending on the surface condition of the printing paper. In contrast, the multicolor recording device according to the present invention forms a mixed primary image of each colored toner on a transfer belt and transfers this mixed primary image to printing paper by applying pressure and heating. This has the advantage that high-quality printing is possible regardless of the condition.

[Brief explanation of drawings]

FIG. 1 is a diagram for explaining the subtractive color mixing method which is a multicolor method of the multicolor recording device according to the present invention, FIG. 2 is a sectional view showing an example of the configuration of the multicolor recording device according to the present invention, and FIG. 2 is a perspective view showing details of the transfer belt 2 shown in FIG. 2, FIG. 4 is a waveform diagram for explaining this embodiment, and FIG. 5 is a diagram showing the printing area E of the plain paper 17. 2...Transfer belt, 2a, 2b...Header mark, 3-5...Thermal head, 6-8...Colored toner supply mechanism (toner supply mechanism), 6c...
Yellow toner (colored toner), 7c... Magenta toner (colored toner), 8c... Cyan toner (colored toner), 9a to 11b... Pressure roller, 1
2 to 14, 18... optical detector (detector), 1
5...Transfer head, 15a...Transfer section (transfer mechanism).

Claims (1)

[Scope of Claims] 1: a transfer belt; a transfer belt driving means for tensioning and running the transfer belt; A plurality of toner supply mechanisms that supply colored toners of different colors, each of which is arranged opposite to each of the toner supply mechanisms with the transfer belt in between, and each of which corresponds to the color of the colored toner supplied by the toner supply mechanism. The transfer belt is heated by being energized according to the data, and primary images of the colored toners in the shape corresponding to the print data are sequentially welded to one surface of the transfer belt, and the primary images of each colored toner are heated. a plurality of thermal heads that form superimposed mixed primary images; and a transfer head that heats the transfer belt and presses it against printing paper to fix the mixed primary image formed on the transfer belt to the printing paper. A multicolor recording device comprising: 2. The multicolor recording apparatus according to claim 1, further comprising a detector provided upstream of the thermal head to determine the timing of energization of each of the thermal heads. 3. The method according to claim 1 or 2, wherein pressure means for pressing the colored toner welded onto the transfer belt is provided on the downstream side of each of the thermal heads. Multicolor recording device. 4. Claims 1 and 2, characterized in that the transfer belt is provided with at least one header mark for determining transfer timing.
The multicolor recording device according to any one of item 3.