JPH0737144B2 - Recording device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Field of Industrial Application> The present invention relates to a recording apparatus that can be used in a printer, a copying machine, a facsimile, or the like.

<Prior Art> In recent years, various information processing systems have been developed along with the rapid development of the information industry, and a recording device suitable for each information processing system has been developed.

There is a thermal transfer recording device as one of the recording devices. In this method, recording is performed on a recording paper using an ink ribbon formed by coating a ribbon-shaped support with a heat-meltable ink prepared by dispersing a colorant in a heat-meltable binder.

That is, the ink ribbon is superposed so that the heat-meltable ink layer contacts the recording paper, and the ink ribbon and the recording paper are conveyed between the thermal head and the platen, and the thermal head is moved from the support side of the ink ribbon. In addition to applying pulsed heat according to the image signal, the two inks are pressed into contact with each other to transfer the melted ink to the recording paper, thereby recording an ink image on the recording paper according to the heat application. .

The above-described recording apparatus has been widely used in recent years because the apparatus used is small and lightweight, has no noise, and can record on plain paper.

<Problems to be Solved by the Invention> However, the conventional thermal transfer recording apparatus is not without problems.

In the conventional thermal transfer recording apparatus, the transfer recording performance, that is, the image quality is greatly affected by the surface smoothness of the recording paper.
Although good image recording is performed on recording paper having high smoothness, image recording quality may be deteriorated in the case of recording paper having low smoothness.

Further, in the conventional thermal transfer recording apparatus, when an attempt is made to obtain a multicolor image, it is necessary to repeat the transfer to superimpose the colors. Therefore, it is necessary to provide a plurality of thermal heads, or to make a complicated movement such as stopping and reverse feeding on the recording paper, and not only color misregistration is unavoidable, but also the entire device becomes large and complicated. There is a problem.

<Means for Solving Problems> Therefore, the present applicant uses a photothermally sensitive material, and when heat energy and light energy are applied, the reaction of the material rapidly progresses and the transfer characteristics are irreversibly changed. As a result, we proposed a recording apparatus which forms an image according to the difference in the characteristics according to the image signal and transfers it to the recording medium (Japanese Patent Application No. 60-150597).
issue).

According to this recording device, it is possible to record a high-quality image even on a recording medium having a low surface smoothness, and when applied to multicolor recording, the recording medium is caused to make a complicated movement. It is possible to obtain a multicolored image without any trouble.

An object of the present invention is to further develop the recording device, and to provide a recording device capable of improving the transferability of an image to a recording medium and the peeling property between the transfer recording medium and the recording medium. To do.

The means therefor is an apparatus for recording an image on a recording medium by using a transfer recording medium having a transfer recording layer whose transfer characteristics are changed by applying a plurality of types of energy. And a recording unit having an applying unit for applying energy to the transfer recording medium provided along the transfer route of the transfer recording medium conveyed by the conveying unit, and the transfer recording medium in the recording unit. A transfer portion for transferring the image formed on the recording medium to a recording medium,
Located on the downstream side of the transfer section in the transport direction of the recording medium,
The transfer unit and the fixing unit have a function of conveying the recording medium, and the transfer speed of the recording medium at the fixing unit is set to the transfer unit. The present invention is characterized in that it has means for slowing the conveyance speed of the recording medium.

<Operation> According to the above means, when the transfer recording medium and the recording medium are set in the apparatus for recording, a plurality of types of energy are applied to the transfer recording medium in the recording section to form an image, and the image is formed. It is transferred onto the recording medium at the transfer portion.

Further, since the conveyance speed of the recording medium in the fixing section is slower than that in the transfer section, the fixing section does not forcibly pull the recording medium. Therefore, the image formed on the transfer recording medium is stably transferred at the transfer portion, and the separation between the transfer recording medium and the recording medium is also stable.

<Example> Next, an example of the present invention to which the above means is applied will be described.

FIG. 1A is a schematic cross-sectional view of the recording apparatus.
FIG. 3B is a perspective explanatory view.

In the figure, reference numeral 1 denotes a transfer recording medium in the form of a long sheet, which is wound around in a roll shape and is detachably incorporated into the apparatus main body M as a supply roll 2. That is, the supply roll 2 is detachably loaded on the rotatable shaft 2a provided on the apparatus main body M.

Therefore, first, the leading end of the transfer recording medium 1 is supplied to the supply roll 2,
After passing through the guide roller 12a, the recording head 3a, and the guide roller 12b, the peeling roller 5 and the guide roller 12c deflect between the transfer roller 4a and the pressure roller 4b to reach the take-up roll 6, and the leading end thereof is wound. The take-up roll 6 is locked by means such as a gripper (not shown). After that, the take-up roll 6 is driven and rotated by a well-known driving means, whereby the transfer recording medium 1 is fed in the direction of arrow a,
The winding roll 6 is sequentially wound around the peripheral surface of the winding roll 6.

During the winding, a constant back tension is applied to the supply roll 2 by, for example, a hysteresis brake (not shown), and the transfer recording medium 1 is moved to the recording head 3a by this tension and the guide rollers 12a and 12b. It is configured to be conveyed while being pressed against it at a constant pressure and at a constant angle.

Further, a fixing unit 13 is arranged downstream of the roller pair 4a, 4b of the transfer unit.

Next, the configuration of each of the above parts will be individually described.

First, as shown in FIG. 2, the transfer recording medium 1 has a transfer recording layer 1b having a property capable of forming an image when both thermal energy and light energy are applied onto a sheet-like support 1a. Become.

To explain one example thereof, as shown in FIG. 2, the transfer recording layer 1b uses the components shown in Tables 1 and 2 as the cores 1c and 1d, and a microcapsule-shaped image forming element is prepared by the following method. Formed.

That is, a mixture of 10 g of the components shown in Tables 1 and 2 was first mixed with 20 parts by weight of methylene chloride, and then a cation or nonionic surfactant having an HLB value of at least 10 or more and 1 g of gelatin.
Was mixed with 200 ml of dissolved water and stirred by a homomixer at 60 ° C with stirring at 8,000 to 10,000 rpm to emulsify and the average particle size
A 26 μm oil drop is obtained.

Further, stirring is continued at 60 ° C. for 30 minutes to distill off methylene chloride so that the average particle diameter becomes 10 μm. To this, add 20 ml of water in which 1 g of gum arabic is dissolved and slowly cool with NH.
Microcapsule slurry is obtained by adding ₄ OH (ammonia) water to pH 11 or above, and 1.0 ml of 20% glutaraldehyde aqueous solution is slowly added to harden the capsule wall.

After that, solid-liquid separation is performed with a Nutche filter and the vacuum dryer is used for 35
After drying at ℃ for 10 hours, a microcapsule-shaped image forming element is obtained.

This image-forming element is a microcapsule in which the cores 1c and 1d in Tables 1 and 2 are coated with the shell 1e, and the particle size is 7 to 15
The average particle size is 10 μm.

To explain this in more detail, Nippon Synthetic Chemical Industry Co., Ltd.
An adhesive 1f made by dissolving 3 cc of toluene in 1 cc of polyester adhesive Polyester LP-022 (solid content 50%) manufactured by the company is applied on a support 1a made of a polyethylene terephthalate film having a thickness of 6 μm. Then, the solvent was dried and removed, and the thickness was measured and found to be about 1 μm. The adhesive 1f has a glass transition point of −15 ° C., so that a slight tack remains at room temperature, and the image forming element body formed as described above can be easily attached to the support 1a.

Next, the microcapsule-shaped image-forming element having the core materials shown in Tables 1 and 2 obtained as described above was used in a ratio of 1: 1.
Were mixed at a ratio of, and sprinkled on this to adhere. After that, when the excess image-forming element was removed, the image-forming element was arranged on the adhesion layer in approximately 1 layer and 90%.

Then, the transfer recording medium 1 is constituted by applying a pressure of about 1 kg / cm ² and heat energy of about 80 ° C. to firmly fix the image forming element on the support 1 a.

The photoinitiator in the image forming element shown in Table 1 above absorbs the light in the band of graph A in the light absorption characteristics of FIG. 3 to start the reaction, and becomes magenta during image formation. The photoinitiator in the image forming element shown in Table 2 absorbs light in the band shown in the graph B of FIG. 3 to start the reaction, and becomes blue at the time of image formation.

Next, the recording unit 3 will be described. The recording unit 3 is composed of heating means and light irradiation means.

The heating means is composed of a line-type heating element array 3b having a width of 0.2 mm and 8 dots / mm of A-4 size and a line type heating element array 3b arranged on the surface of the recording head 3a to generate heat according to an image signal. The support 1a side of the medium 1 is configured to come into pressure contact with the heating element array 3b with a predetermined pressure due to back tension during transportation. The image signal is emitted from a control unit (not shown) such as a facsimile, an image scanner, or an electronic blackboard according to the purpose.

On the other hand, on the side of the transfer recording layer 1b facing the recording head 3a, two fluorescent lamps 3c and 3d, which are 20 W type light irradiating means having spectral characteristics as shown in FIG. ~ 3
They are placed 5 mm apart.

Further, the housing 3e is approximately 0.5 mm from the transfer recording medium 1 so that the direct light of the fluorescent lamps 3c and 3d is irradiated only to the region directly above the heating element array of the transfer recording medium 1 which is pressed against the recording head 3a.
The distance is maintained so that the opening width is 0.5 mm.

In this embodiment, as one of the fluorescent lamps 3c having the spectral characteristics shown in the graph A of FIG.
The W health line fluorescent lamp FL20SE is used, and as the other fluorescent lamp 3d having the spectral characteristics shown in Graph B, a 20W fluorescent lamp FL10A70E39 manufactured by Toshiba Corporation is used.

Next, the transfer unit 4 will be described. The transfer section 4 is arranged on the downstream side of the recording section 3 in the conveying direction of the transfer recording medium 1, and is in press contact with the transfer roller 4a which is driven and rotated in the direction of arrow b as shown in FIG. It is composed of a pressure roller 4b. The transfer roller 4a has a surface of 1 mm.
It is composed of an aluminum roller covered with a thick silicon rubber having a hardness of 70 degrees, and the surface thereof is maintained at 90 to 100 ° C. by a built-in 800 W halogen heater 4c.

The pressure roller 4b is made of silicone rubber with a hardness of 70 degrees.
It consists of an aluminum roller coated with a thickness of 1 mm, and the pressing force against the transfer roller 4a is 6 by a pressing means (not shown) such as a spring.
It is set to ~ 7kgf / cm.

Further, a recording paper 8 which is a recording medium loaded in the cassette 7 is provided.
By the feeding roller 9 and the register roller pair 10a, 10b,
It is configured to be fed to the transfer section 4 in synchronization with the image area of the transfer recording medium 1 so as to overlap with the image area.

Next, the fixing unit 13 will be described. The fixing unit 13 is arranged on the downstream side of the transfer unit 4 in the conveying direction of the recording paper 8, and the fixing roller 13a and the pressure roller 13b are formed of springs or the like (not shown). The pressing force of both is set to 10 to 12 kgf / cm by the pressing means, and the heater 13c built in the fixing roller 13a
The surface of the roller 13a is kept at 120 to 130 ° C.

The transfer section 4 and the fixing section 13 have a function of conveying the recording paper 8. That is, the transfer roller 4a and the fixing roller 13a are configured to be driven and rotated by the driving means 14.

The drive means 14 will be described below. As shown in FIG. 1B, a drive motor 14b is connected to the transfer roller 4a via a gear train 14a, and the transfer roller 4a is moved in the direction of arrow b by the motor 14b. The transfer recording medium 1 and the recording paper 8 are driven and rotated, and the transfer recording medium 1 and the recording paper 8 are conveyed by this rotation.

The driving means 14 is also connected to the fixing section 13. That is, the drive motor 14b is a double shaft motor, and the other shaft of the motor 14b is the pulley 14c and the timing belt 14b.
d, further connected to the fixing roller 13a via a gear train 14e.

The transmission of the driving force by the motor 14b is performed by the gear train 14a.
The rotational peripheral speed of the fixing roller 13a is set to be about 0.2% slower than the rotational peripheral speed of the transfer roller 4a by changing the gear ratios of 14e and 14e.

Next, the operation when recording is performed by the recording apparatus configured as described above will be described.

In the embodiment described below, heat is applied according to an image signal and light is applied uniformly.

A motor (not shown) is driven to sequentially feed the transfer recording medium 1 from the supply roll 2, and light and heat are applied to the transfer recording layer 1b of the transfer recording medium 1 in the recording unit 3 according to an image signal to form an image. To be done.

That is, since the transfer recording layer 1b has a property that the softening point temperature rises when light and heat of a predetermined wavelength are applied and the transfer recording layer 1b is not transferred to the recording paper 8, as shown in the timing chart of FIG. At the time of magenta color recording, the heating element corresponding to magenta of the image signal is not energized in the heating element array 3b, and the portion corresponding to white of the image signal (recording paper 8 is white) is 25 ms.
Then, the fluorescent lamp 3c is uniformly irradiated with a delay of 5 ms. The irradiation time at this time is 45 ms.

Next, at the time of blue recording, 50 ms after the end of irradiation, that is, 100 ms after the energization time, this time, the heating element corresponding to blue of the image signal in the heating element row 3b is not energized and the image signal of Energize for 25ms to the part corresponding to white, and 5ms
After that, the fluorescent lamp 3d is uniformly irradiated. The irradiation time at this time is also 45 ms as described above.

As described above, the recording head 3a is controlled according to the blue, magenta, and white image signals to form a negative image on the transfer recording layer 1b, and the transfer recording medium 1 is synchronized at a repeating cycle of 200 ms / line. To transport. Further, in the transfer section 4, the transfer recording layer 1b on which the image has been formed is pressed against the recording paper 8 and heated to transfer the transferred images of two colors, blue and magenta, to the recording paper 8.

After that, the transfer roller 1 and the recording paper 8 are moved by the peeling roller 5.
The transfer recording medium 1 is taken up by a take-up roll 6, and the recording paper 8 on which an image of a desired color is recorded is fixed to the fixing unit.
Transported to 13.

The recording paper 8 conveyed to the fixing unit 13 rotates the fixing roller 13
Pressure is applied between a and the pressure roller 13b that follows it, and it is heated to a predetermined temperature by the heater 13c, whereby the transfer image is firmly fixed on the recording paper 8, and the recording paper 8 is placed on the discharge tray 11. Is discharged.

In the fixing section 13, the peripheral speed of rotation of the fixing roller 13a is set to be slightly lower than the peripheral speed of rotation of the transfer roller 4a, so that the recording paper 8 is located between the transfer section 4 and the fixing section 13. In addition, the recording paper 8 is conveyed while causing a slack due to the difference in speed between the rollers 4a and 13a. Therefore, the fixing roller 13a does not forcibly pull the recording paper 8 at the time of transferring an image at the transfer portion 4 and at the time of separating the transfer recording medium 1 and the recording paper 8 at the peeling roller 5, so that the transferability is improved. Moreover, the peelability is not adversely affected, and as a result, an image having extremely stable image quality is transferred and recorded.

As described above, two-color recording in which the transferred image is stable is performed by one shot.

<Other Embodiments> In the above-described embodiments, the rotational peripheral speed of the fixing roller 13a is set to be slightly slower than that of the transfer roller 4a by changing the gear ratio. However, the present invention is limited to the case of using a gear train. However, other deceleration systems may be used.Furthermore, the transfer roller 4a and the fixing roller 13a are driven by different motors, respectively, and the rotational peripheral speed of the fixing roller 13a is changed by changing the rotational speeds of both motors. May be slowed down.

Further, the members forming the transfer unit 4 and the fixing unit 13 are not limited to the roller-shaped members as described above, and may be any structure such as a rotary belt that can obtain a desired pressure.

Next, another embodiment of the recording unit 3 will be described.

In the above-described embodiment, in the recording unit 3, the transfer recording layer 1b side of the transfer recording medium 1 is uniformly irradiated with light of a predetermined wavelength corresponding to a desired color, and the support 1a side receives an image signal. However, as another embodiment, the heat may be uniformly applied and predetermined light may be applied in accordance with the image signal.

If the support 1a is made of a light-transmissive material, the support 1a may be irradiated with light and the transfer recording layer 1b may be applied with heat.

Further, in the above-described embodiment, light irradiation and heat application were performed with the support 1a sandwiched between them. However, image formation is also possible by separately performing light irradiation and heat application from one side of the support 1a. .

As the heating means, in addition to the method of using the recording head 3a described above, a method of selectively heating using a YAG laser and a polygon mirror may be used.

As the light irradiation means, in addition to the method using the fluorescent lamps 3c and 3d described above, for example, a method using an LED array or a method using a xenon lamp and a filter matching the light absorption characteristics of the material can be used.

In the above-mentioned embodiment, the light energy and the heat energy are applied to the transfer recording layer 1b at the same time. However, even if the light energy and the heat energy are applied separately, as a result, both energy Any configuration may be used as long as it is provided.

Further, in the above-mentioned embodiment, an example of two-color recording is explained, but as the applicant of the present application has clarified in Japanese Patent Application No. 61-128814, the kinds of the colorant and the photoinitiator constituting the image forming element are selected. It is also possible to obtain a monochromatic, multicolor of three or more colors, or a full-color recorded image by appropriately selecting a light source having a wavelength that reacts with the photoinitiator and using the process according to the application.

Further, in the above-mentioned embodiment, an example in which an image is transferred and recorded on the recording paper by the change of the softening point temperature of the transfer recording layer 1b of the material containing the colorant by the light energy and the heat energy is shown. An image may be transferred and recorded depending on the adhesive property to paper or the sublimation property. Alternatively, an image can be recorded by providing a layer on the transfer recording medium that gives the recording paper a color forming property and changes the color forming characteristics of the recording paper, and transferring the image formed on the transfer recording medium to the recording paper. It may be configured to obtain.

The plurality of types of energy applied to the transfer recording layer 1b are not limited to the heat and light energy described above, and an image may be formed by other energy such as pressure energy.

Further, as the material of the support 1a, in addition to the above-mentioned polyethylene terephthalate, for example, polyamide, polyimide, condenser paper, cellophane paper or the like can be used.

As the transfer recording layer 1b, a material having properties such as heat melting property, heat softening property, or heat sublimation property can be appropriately selected and used.

Further, the recording medium is not limited to the above-mentioned recording paper, and may be, for example, an overhead projector (OH
Of course, plastic sheets for P) can also be used.

<Effects of the Invention> As described above, according to the present invention, an image is formed on a transfer recording medium and then this image is transferred to the recording medium. Therefore, an image can be formed on a recording medium having a relatively low surface smoothness. Can be recorded satisfactorily. When the present invention is applied to multicolor recording, a multicolor image can be obtained without causing complicated movement of the recording medium.

Further, since the recording medium conveyance speed in the fixing unit is slower than the conveyance speed in the transfer unit, the recording medium is not forcibly pulled by the fixing unit, and as a result, the image transferability and the recording medium The peelability from the transfer recording medium is good, clear image transfer can be performed, and the transferred image can be firmly fixed.

[Brief description of drawings]

FIGS. 1 (A) and 1 (B) are schematic explanatory views of one embodiment of the present invention, FIG. 2 is a structural explanatory view of a transfer recording medium, and FIG. 3 is an absorption characteristic of a photoinitiator in the transfer recording medium. Explanatory drawing showing
FIG. 5 is an explanatory diagram showing the spectral characteristics of the light irradiation means, and FIG. 5 is a timing chart for applying heat and light. 1 is a transfer recording medium, 1a is a support, 1b is a transfer recording layer, and 1c, 1
d is a core, 1e is a shell, 1f is an adhesive, 2 is a supply roll, 2
a is a supply roll shaft, 3 is a recording unit, 3a is a recording head, 3b is a heating element array, 3c and 3d are fluorescent lamps, 3e is a slit plate, 4 is a transfer unit, 4a is a transfer roller, 4b is a pressure roller, 4c is a heater,
5 is a peeling roller, 6 is a take-up roll, 7 is a cassette, 8
Is a recording sheet, 9 is a feeding roller, 10a and 10b are register rollers, 11 is a discharge tray, 12a, 12b and 12c are guide rollers, 13
Is a fixing unit, 13a is a fixing roller, 13b is a pressure roller, 13c is a heater, 14 is driving means, 14a gear train, 14b is a motor,
14c is a pulley, 14d is a timing belt, and 14e is a gear train.

Claims (2)

[Claims] 1. An apparatus for recording an image on a recording medium by using a transfer recording medium having a transfer recording layer whose transfer characteristics are changed by applying plural kinds of energy.
A transport unit that transports the transfer recording medium, a recording unit that has an applying unit that applies energy to the transfer recording medium that is provided along the transport path of the transfer recording medium that is transported by the transport unit, and the recording unit. Transfer unit for transferring the image formed on the transfer recording medium to the recording medium, and fixing for fixing the transferred image to the recording medium, which is located downstream of the transfer unit in the conveyance direction of the recording medium. And a transfer unit and a fixing unit have a function of conveying the recording medium, and a means for making the conveying speed of the recording medium in the fixing unit slower than the conveying speed of the recording medium in the transfer unit. A recording device having: 2. The recording apparatus according to claim 1, wherein the plurality of types of energy are composed of thermal energy and light energy.