JPS62181184A - Laser thermal transfer recorder - Google Patents

Abstract

PURPOSE:To simplify a taking-up and feeding mechanism for a thermal transfer film and enhance efficiency in use of the film, by inclining the feeding direction of the thermal transfer film at a predetermined angle to the scanning direction of a laser beam. CONSTITUTION:A ribbon form thermal transfer film 13 is stretched over a recording paper 11 at a predetermined angle to the longitudinal direction of a platen 12, and is pushed to the side of the paper 11 with a predetermined tension. The film 13 is fed in the longitudinal direction thereof, i.e., the direction of an arrow B' at a predetermined speed by a taking-up and feeding mechanism. A laser beam is scanned on predetermined positions which are not moved, whereby the entire surface of the film 13 can be irradiated with the laser beams. Accordingly, by only continuously taking up the film 13 at a fixed speed during printing, the film 13 can be used wastelessly and completely.

Description

Detailed Description of the Invention (Technical Field) The present invention relates to a laser thermal transfer recording device, and particularly to a laser thermal transfer recording device that transfers an information image onto recording paper by irradiating a ribbon-shaped thermal transfer film with laser light. It relates to a recording device.

(Prior Art) In recent years, a laser thermal transfer recording apparatus has been developed in which a thermal transfer film is brought into close contact with a recording paper, and printing is performed by irradiating laser light onto the thermal transfer film. This laser thermal transfer recording device has longer lifespan, reliability, and
Noise 9 image quality.

It is excellent in all aspects of image preservation and has a fast recording speed.

In such a laser thermal transfer recording apparatus, the thermal transfer film and the recording paper are each transported and wound up in a predetermined direction by a transporting means.

That is, as shown in FIG. 7, a recording paper 2 is set on a plate-shaped platen 1 which is curved into a cylindrical shape, and a ribbon-shaped thermal transfer film 3 is placed on the recording paper 2.
is spread across the recording paper 2 in the width direction of the platen 1.

The thermal transfer film 3 is wound in its longitudinal direction (in the direction of arrow B), and is therefore wound in the direction of conveyance of the recording paper 2 (in the direction of arrow B).
It is transported perpendicular to the six directions of arrows). Then, laser light 5 deflected by a deflector consisting of a rotating polygon mirror 4 is irradiated onto the thermal transfer film 3, thereby performing predetermined recording.

At this time, conventionally, the laser beam used for recording is scanned in the longitudinal direction of the thermal transfer film 3.

As shown in FIG.
As shown in the figure, there are cases where a plurality of laser beams are scanned over the entire width of the thermal transfer film 3 while sequentially changing their positions in the width direction.

The 80th scan has the advantage that the thermal transfer film 3 can be continuously wound at a constant speed during printing, and the winding and conveying mechanism can be simplified. They are used with a lot of them remaining, and there is a lot of waste.

Further, in the scanning shown in FIG. 9, the thermal transfer film 3 can be used efficiently without waste, but the thermal transfer film 3 cannot be used until the entire width of the thermal transfer film 3 has been scanned.
must be held in the same place for a certain period of time. Therefore, the thermal transfer film 3 must be fed intermittently, which complicates the winding and conveying mechanism. Moreover, the scanning position of the laser beam must be changed sequentially in the width direction of the thermal transfer film 3, and the scanning mechanism is also complicated.

(Purpose) Therefore, an object of the present invention is to provide a laser thermal transfer recording device that simplifies the winding and conveying mechanism for the thermal transfer film and can improve the utilization efficiency of the thermal transfer film.

(Structure) In order to achieve the above object, the laser thermal transfer recording device according to the present invention is configured such that the conveyance direction of the thermal transfer film is set in an oblique direction forming a predetermined angle with respect to the scanning direction of the laser beam.
As the thermal transfer film is wound up and conveyed, unused thermal transfer film is continuously supplied to the scanning position of the laser beam.

Hereinafter, the configuration of the present invention will be explained in detail based on examples.

As shown in FIGS. 1 and 2, the recording paper 11 is placed on a platen 12 of a predetermined length, which is curved so as to constitute a part of a cylindrical body, and is transferred to the platen by a transport mechanism (not shown). It is sent in the direction of the arrow along the 120 curved surface.

Furthermore, a ribbon-shaped thermal transfer film 13 is stretched obliquely over the recording paper 11 at a predetermined angle with respect to the longitudinal direction of the platen 12, and is pressed against the recording paper 11 side with a predetermined tension. And the above thermal transfer film 1
3 is conveyed at a predetermined speed in its longitudinal direction, that is, in the force direction of arrow B', by a winding and conveying mechanism (not shown). Therefore, the conveyance direction of the recording paper 11 (in the direction of the arrow),
The feeding direction of the thermal transfer film 13 (arrow B' is not perpendicular to the force direction).

In this case, the laser beam scans in the width direction of the recording paper 11 regardless of the direction in which the thermal transfer film 13 is transported. In other words, the laser beam is scanned in a direction perpendicular to the feeding direction of the recording paper 1, and as a result, the winding and conveying direction of the thermal transfer film 13 is set obliquely to the scanning direction of the laser beam. ing.

Further, the laser beam generated from the semiconductor laser 14 is collimated by the collimating lens 15 and is then collimated by the rotating polygon mirror 1.
After that, the fθ lens 17
The light is divided into equal parts, roughly corrected and shaped by the cylindrical lens 18, and then irradiated onto the thermal transfer film 13. As a result, predetermined recording is performed.

Note that, as shown in FIG. 3, the thermal transfer film 13 includes a heat-melting ink layer 21 with a thickness of approximately 4 μm to 6 μm;
It is composed of an ink support layer 22 with a thickness of about 3.5 μm to 10 μm that supports this, and the heat-fusible ink layer 21 side is in close contact with the recording paper 11, and the laser beam is emitted from the ink support layer 22 side. It is now irradiated.

In a laser thermal transfer recording apparatus having such a configuration, a recording paper 11 is placed on a curved platen 12 along the curved surface of the platen 12, and a thermal transfer film 13 is further placed on the recording paper 11. is passed diagonally. As a result, the thermal transfer film 13 wraps around the curved surface of the platen 12 and wraps around the recording paper 11.
It is completely adhered to the top. Then, it is transported in the direction of arrow B' and wound up.

Further, the conveyance direction of the thermal transfer film 13 is set to be diagonal at a predetermined angle with respect to the scanning direction of the laser beam. Therefore, when the thermal transfer film 13 is continuously wound and conveyed, the unused portion of the thermal transfer film 13 is continuously supplied to the scanning position of the laser beam. If the laser beam is scanned at a fixed position without moving the scanning position, the laser beam will be transferred to the thermal transfer film 13.
can be irradiated over the entire surface. Therefore, during printing, simply by winding up the thermal transfer film 13 continuously at a constant speed, the thermal transfer film 13 can be used completely without any waste.

Furthermore, the present invention is applicable not only to a device using a deflector made of the rotating polygon mirror 16 as described above, but also to a device using a hologram scanner 23 as a deflector as shown in FIGS. 4 and 5. be able to. The hologram scanner 23 has holograms, which are cooperative elements, arranged on a disk substrate 24, and a laser beam from a laser light source (not shown) passes through a cylindrical lens 25, is reflected by a plane mirror 26, and enters one of the holograms. , after the diffracted light generated from the hologram is reflected by the plane mirror 27,
Irradiation is performed through an fθ lens and a cylindrical lens 29.

Furthermore, as a light source, in addition to the semiconductor lens mentioned above, a helium-neon laser, an argon ion laser,
A YAG laser, a carbon dioxide laser, a helium-cadmium laser, or the like can also be used. In this case,
As shown in FIG. 6, the laser beam emitted from the laser 31 passes through a beam compressor 32, an AO modulator 33, a beam expander 34, a cylindrical lens 35, and is deflected by a rotating polygon mirror 36, and then is deflected by a toroidal lens. 3
7 and an fθ lens 38 to illuminate the recording material 39.

(Effects) As described above, the laser thermal transfer recording device according to the present invention can perform thermal transfer so that unused thermal transfer film is continuously supplied to the scanning position of the laser beam as the thermal transfer film is wound up and conveyed. Since the film transport direction is set diagonally at a predetermined angle with respect to the scanning direction of the laser beam, the thermal transfer film can be continuously wound at a constant speed, simplifying the winding and transport mechanism. be able to. Furthermore, the thermal transfer film can be used efficiently without waste, and extremely economical recording can be performed.

[Brief explanation of drawings]

1 and 2 are perspective views of a recording device in one embodiment of the present invention, FIG. 3 is a cross-sectional configuration diagram of a thermal transfer film, and FIGS. 4, 5, and 6 are other embodiments of the present invention. A perspective view showing an optical system in an example, and FIGS. 7, 8, and 9 are perspective views of a conventional recording apparatus. 11... Recording paper, 12... Platen, 13...
Thermal transfer film, 14.31... Laser, 15...
Collimator lens, 16.36...Rotating polygon mirror, 17
゜28.38...fθ lens, 18.25.29゜3
5... Cylindrical lens, 23... Hologram scanner, 24... Disk, 26.27... Plane mirror, 32... Beam compressor, 33... AO modulator, 34... Beam expander , 37... Toroidal lens, 39... Recording material. Osamu J Iwo

Claims (1)

[Claims] Place the recording paper on a cylindrical curved platen,
A laser that transfers an information image onto the recording paper by irradiating the thermal transfer film with a laser beam while scanning it in a predetermined direction while a ribbon-shaped thermal transfer film is brought into close contact with the recording paper and rolled up and conveyed. A laser thermal transfer recording device characterized in that the winding and conveying direction of the thermal transfer film is set in an oblique direction forming a predetermined angle with respect to the scanning direction of laser light.