JPH03187783A - Thermal transfer recording method - Google Patents

Abstract

PURPOSE:To shorten the irradiating time and to increase the recording speed by using an ink sheet containing conductive substance for an ink layer and, making the surface of a supporting body conductive, and radiating laser beams while impressing a voltage between the supporting body and ink layer of the ink sheet. CONSTITUTION:An ink sheet 5 has an ink layer 6 on a base material 7. The ink layer 6 is brought in tight contact with a recording paper 4 which is pressed against a supporting body 1. In this state, the ink of the ink layer when irradiated with laser beams from the base material 7 is melted and transferred to the recording paper 4. The ink sheet 5 containing a conductive substance is used for the ink layer 6. The surface of the supporting body 1 is made conductive. Laser beams are projected while a voltage is impressed between the supporting body 1 and ink layer 6 of the ink sheet 5. since the ink layer 6 of the ink sheet 5 is made conductive, and an electric field is allowed to act on the ink, the viscosity generated when the ink is softened by heat is added with the Coulomb energy. Accordingly, the heating time can be shortened and the recording speed is improved.

Description

Detailed Description of the Invention [Summary] An ink sheet having an ink layer on a base material is brought into close contact with the ink layer facing the recording paper side, the recording paper is pressed against the support, and the base material Regarding thermal transfer recording, in which the ink in the ink layer is melted and transferred to recording paper by irradiating it with a laser beam as a heat source, even when using a semiconductor radar as the heat source, the irradiation time can be shortened and the recording speed can be increased. For the purpose of speeding up the process, an ink sheet containing a conductive substance is used in the ink layer, the surface of the support is made conductive, a constant voltage is applied between the support and the ink layer of the ink sheet, and a laser beam is applied. A thermal transfer recording method is provided in which gradation recording is performed by controlling the irradiation energy of a beam.

[Industrial application field]

The present invention relates to a thermal transfer recording method, in particular, an ink sheet having an ink layer on a base material, which is brought into close contact with the ink layer facing the recording paper side, and the recording paper is pressed against a support, and at the same time, from the base material side. The present invention relates to a thermal transfer recording method in which ink in an ink layer is melted and transferred onto recording paper by irradiating a laser beam as a heat source.

Further, the present invention provides an ink sheet having an ink layer on a base material capable of recording density gradation in units of dots, the ink layer is brought into close contact with the recording paper side, and the recording paper is placed against the support. The present invention relates to a thermal transfer recording method in which ink in an ink layer is melted and transferred to recording paper by pressing and irradiating a laser beam as a heat source from the side of the base material.

The thermal transfer recording method using an ink sheet has features such as a simple structure and easy miniaturization, and is therefore widely used as a recording method for small printers. In particular, when high-precision recording is required, a recording method using a high-resolution laser beam as a heat source is preferable.

[Conventional technology]

A thermal transfer recording method using a semiconductor laser as a heat source instead of a thermal head has already been proposed. In this way, when a semiconductor laser that can be mounted on a small recording device is used as a heat source, the beam diameter can be narrowed down to a few microns, resulting in significantly improved recording resolution compared to conventional thermal heads, which have a dot size of several tens of microns. .

In addition, in the thermal transfer recording method that uses a melt-type ink sheet that can perform dot gradation recording, the amount of ink transferred to the recording paper is approximately proportional to the amount of heat from the thermal head, so a semiconductor laser is used instead of the thermal head. In this case, dot-by-dot density gradation can be achieved by controlling the irradiation energy of the laser beam.

[Problem to be solved by the invention]

However, the thermal energy that can be generated by current semiconductor lasers is lower than that of thermal heads, and when semiconductor lasers are used, the irradiation time must be increased accordingly, resulting in a problem that the recording speed becomes slower.

Therefore, an object of the present invention is to provide a thermal transfer recording method that can shorten the irradiation time and therefore increase the recording speed even when a semiconductor laser is used instead of a thermal head.

[Means to solve the problem]

In order to solve such problems, according to the first invention, as shown in FIG. The recording paper 4 is pressed against the support 1 while the ink in the ink layer is melted and transferred to the recording paper 4 by irradiating the base material 7 with a laser beam as a heat source. In thermal transfer recording, the ink sheet 5 containing a conductive substance is used as the ink layer 6, the surface of the support 1-f) is made conductive, and the ink layer 6 of the support 1 and the ink sheet 5 is
Provided is a thermal transfer recording method characterized in that a laser beam is irradiated while applying a voltage between.

Further, according to the second invention, as shown in FIG.
The ink sheet 10 provided above is brought into close contact with the ink layer 13 facing the recording paper 4 side, the recording paper 4 is pressed against the support 1, and a laser beam is irradiated from the base material 11 side as a heat source. In thermal transfer recording in which the ink in the ink layer 13 is melted and transferred to the recording paper 4 by
The surface of the support 1 is made conductive, a constant voltage is applied between the support 1 and the ink layer 13 of the ink sheet 10, and the irradiation energy of the laser beam is controlled to perform gradation recording. A thermal transfer recording method is provided.

[For production]

According to the first invention, since the ink layer 6 of the ink sheet 5 is made conductive and an electric field is applied to the ink,
Conventionally, ink was transferred from the base material to the recording paper only by the adhesiveness generated by softening the ink by heating, but in the present invention, the heating time is shortened by further applying Coulomb force from an electric field. However, recording can be performed in the same manner as before, and the recording speed can be improved.

According to the second invention, since the transfer of the ink to the recording paper 4 is performed by the capillary force of the ink generated by heating and the Coulomb force, the irradiation time with the laser beam can be shortened, and therefore high-resolution recording can be performed at high speed. It can be done with

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The configuration of a first embodiment of the present invention will be explained with reference to FIG.

The recording paper 4 and the ink sheet 5 are pressed against each other by a platen (support) 1 and a transparent platen 2. The ink sheet 5 is composed of a base material 7 and an ink layer 6, and the ink layer 6 is in contact with the recording paper 4. A laser beam emitted from an optical system 3 including a semiconductor laser passes through a transparent platen 2 to an ink sheet 50.
The ink is absorbed into the ink layer 6 through the base material 1 and heats the ink in the ink layer 6. An arbitrary thermal pattern is formed on the ink sheet 5 by rotating the platen 10 and scanning the laser beam.

The ink sheet 5 is brought into pressure contact with the voltage application roller 8 and the feed roller 9, and by rotating these rollers 8 and 9 in synchronization with the rotation of the platen 1, the ink sheet 5 is conveyed in the direction of arrow P. The voltage application roller 8 is in contact with the ink layer 6 and applies a voltage. On the other hand, the platen 1 is conductive and electrically grounded. Furthermore, since the ink layer 6 contains conductive substances such as carbon black, surfactant, and polyethylene glycol, a Coulomb force Q acts between the platen 1 and the ink layer 6 via the recording paper 4, causing melting. The ink is quickly transferred to the recording paper 4.

That is, since the ink in the ink layer 6 can be transferred to the recording paper 4 using two forces, adhesive force and electrostatic force, the transfer speed of the ink to the recording paper 4 is improved, so that the laser beam irradiation time can be reduced. can be made shorter, enabling high-speed recording.

In the first embodiment described above, the applied voltage was set to 800V. Irradiation energy by laser is 15mJ/cd
It is.

Conventionally, the laser irradiation energy was 30 mJ/cnf, so according to this embodiment, the recording speed was doubled. Note that since the recording dot is approximately 10 pm, the diameter of the recording dot is 2500 pm.
High resolution recording of dots/inch is possible.

Next, the configuration of a second embodiment of the present invention will be explained with reference to FIG.

As in the first embodiment, 3 in the figure is a laser optical system, 2 is a transparent platen, and 1 is a conductive platen. ink sheet 10
The recording paper 4 is pressed into contact with the transparent platen 2 and the conductive platen 1, and the conductive platen 1 is electrically grounded. The ink sheet 10 is composed of a base material 11, an intermediate adhesive layer 12, and an ink layer 13. The ink layer 13 is made up of an ink 14 and a filler 15, and the ink 14 melted by laser irradiation penetrates into the capillary tubes formed by the recording paper 4 through gaps in the stone wall formed by the filler 15 and is transferred thereto.

The base material 11 was a polyethylene terephthalate film with a thickness of 5 mm, and the intermediate adhesive layer 12 was coated with a polyamide resin and carbon black dissolved in a solvent at a weight ratio of 3:1 using a bar coater so as to have a thickness of 2 mm.

The ink layer 13 is 10 m thick and contains dye, polyethylene glycol, carbon black, fatty acid amide, and surfactant in a weight ratio of 1:0.5:2:3:0.01.
was dissolved in a solvent and applied with a bar coater.

On the other hand, when the ink sheet 10 is conveyed while being pressed by the feed roller 9 and the electrode roller 8, and a voltage is applied to the electrode roller 8, the ink layer 13 is formed of polyethylene glycone carbon black, surfactant, etc. as described above. Since it contains a conductive substance, an electrostatic force Q acts on the ink at a position opposite to the conductive platen.

That is, the ink in the ink layer 10 is melted by irradiation by the laser optical system 3, oozes out from between the fillers 15, and is transferred to the recording paper 4, while the platen 1 is conductive and electrically grounded. Therefore, by applying a voltage to the electrode roller 8, a voltage is applied between the conductive platen 1 and the ink layer 130, and an electrostatic force Q acts between the molten conductive ink 14 and the conductive platen 1. The forces with which the ink 14 permeates into the recording paper are capillary force and electrostatic force. In order to obtain the same ink transfer density as in the past, the capillary force can be reduced, and the irradiation energy of the laser beam, that is, the irradiation time can be shortened.

In the second embodiment, the voltage was kept constant at 800 V, and the laser irradiation energy was changed in 16 steps from 0 to 15 mJ/aI11, thereby making it possible to record 16 gradations. Conventional laser irradiation energy is 0 to 30 mJ/c
Since it is AF, the recording speed has been approximately doubled.

In this second embodiment, a case has been described in which a gradation recording ink sheet IO with a stone wall structure is used, but the present invention can also be applied to other methods capable of melting type gradation recording.
A similar effect can be obtained.

〔Effect of the invention〕

As explained above, according to the present invention, the ink penetration force into the recording paper can be achieved by two forces: adhesive force and electrostatic force, or capillary force and electrostatic force. The speed is improved and therefore the recording speed can be increased. It is also possible to improve the density instead of increasing the speed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a first embodiment of the invention, and FIG. 2 is a schematic diagram of a second embodiment of the invention. 1... Conductive platen, 2... Transparent platen,
3... Optical system including a semiconductor laser, 4... Recording paper, 5... Ink sheet, 6... Ink layer, 7... Base material, body...
- Voltage application roller, 10... Ink sheet, 12... Intermediate adhesive layer, 14... Ink, 9... Feed roller, 11... Base material, 13... Ink layer, 15...・Filling material.

Claims (1)

[Claims] 1. An ink sheet (5) having an ink layer (6) on a base material (7) is brought into close contact with the ink layer facing the recording paper (4) side, and the recording paper is placed on a support. While pressing against (1),
In a thermal transfer recording method in which ink in an ink layer is melted and transferred to recording paper by irradiating a laser beam as a heat source from the side of the substrate, an ink sheet (5) containing a conductive substance is included in the ink layer (6). Thermal transfer is characterized in that the surface of the support (1) is conductive and a laser beam is irradiated while applying a voltage between the support (1) and the ink layer (6) of the ink sheet. Recording method. 2. Ink layer (13
) on the base material (11),
The ink layer is brought into close contact with the recording paper side, and the recording paper (4)
In thermal transfer recording, the ink layer (6) is pressed against the support (1) and irradiated with a laser beam as a heat source from the base material side to melt the ink in the ink layer and transfer it to the recording paper. An ink sheet (10) containing a conductive substance is used, the surface of the support (1) is made conductive, and the ink layer (13) of the support (1) and the ink sheet is
A thermal transfer recording method characterized by performing gradation recording by applying a constant voltage between them and irradiating a laser beam with controlled energy.