JPS62128788A - Laser thermal ink-transfer recorder - Google Patents

Abstract

PURPOSE:To make the good recording by a small laser output possible, by setting the irradiation spot diameter of laser light at approx. two times the dot diameter of the information image to be transferred. CONSTITUTION:The laser light generated from a semiconductor laser 14 is collimated with a collimator lens 15 and deflected with a revolving polygon mirror 16. Thereafter, its speed is equalized with an ftheta lens 17. Further, it is corrected to be reformed with a cylindrical lens 18 and directed on a thermal ink-transfer film 13 like converging in a spot state. In that case, the irradiation spot diameter S of the laser light to be directed on the thermal ink-transfer film 13 is set at approx. two times the dot diameter D of the information image to be transferred. Thereby, the laser energy most effectively operates and the required laser output is minimized. Therefore, a small-sized, low-price laser thermal ink-transfer recorder can be obtained.

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.

This invention relates to a laser thermal transfer recording device that uses a thermal transfer film.

(Conventional technology) In recent years, thermal transfer film has been attached to recording paper.

A laser thermal transfer recording apparatus has been developed which performs print recording by irradiating laser light onto the thermal transfer film 11. This laser thermal transfer device is superior to a conventional thermal recording device using a thermal head in terms of lifespan, reliability, noise, image quality, and image storage stability, and also has a faster recording speed.

In such a laser thermal transfer recording device, 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 platen platen 1 which is curved into a cylindrical shape, and a recording paper 2 is placed on the recording paper 2.

A ribbon-shaped thermal transfer film 3 is stretched across the recording paper 2 in the width direction of the platen 1. The thermal transfer film 3 is wound up in its longitudinal direction (arrow B
direction), and is transported perpendicular to the transport direction (direction of arrow A) of the recording paper 2. And rotating polygon @
A laser beam 5 deflected by a deflector 4 is irradiated onto the thermal transfer film 3, thereby performing predetermined recording.

However, in the conventional apparatus, it is necessary to generate a high-output laser beam to melt the ink layer of the thermal transfer film, making the entire apparatus large and expensive. In particular, there is a certain limit to the output power of semiconductor lasers, and it is often impossible to use small, low-cost semiconductor lasers.

(Objective) Therefore, an object of the present invention is to provide a laser thermal transfer recording device that can perform good recording with a small laser output.

(Structure) Hereinafter, the structure 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. It is sent in the direction of arrow A along the curved surface of 12.

Furthermore, a ribbon-shaped thermal transfer film 13 is stretched obliquely over the recording paper II at a predetermined angle with respect to the width direction of the platen 12, and is pressed against the recording paper II with a predetermined tension. A winding mechanism (not shown) transports the winding film at a predetermined speed in its longitudinal direction, that is, in the direction of arrow B'. Therefore, the above-described feeding direction of the recording paper 11 (direction of arrow entry) and feeding direction of the thermal transfer film 13 (direction of arrow B') are not perpendicular to each other.

Further, the laser light generated from the semiconductor laser 14 is as follows.

After being collimated by the collimator lens 15 and deflected by a deflector consisting of a rotating polygon mirror 16, the fθ lens 17
The cylindrical lens 18 corrects and shapes the irradiation onto the thermal transfer film 13 so as to converge it into a spot.
The ink layer 3 is appropriately melted to record a predetermined information image on the recording paper 11.

In this case, as shown in FIG. 3, the dot diameter of the information image to be transferred is, for example, 100 μm.

The irradiation spot diameter S of the laser beam irradiated onto the thermal transfer film 13 is set to about twice that diameter, for example, 200 μm.

In this way, the laser energy is most efficiently applied and requires the least amount of laser power. That is,
The laser output is Po, and the dot radius of the information image to be transferred is x.
(x=D/2), and the laser beam irradiation spot radius is w(
w=S/2).

It was experimentally and empirically confirmed that the following formula holds true. Here, if we consider X to be a constant and differentiate the above equation with respect to W, we get:

It is found that the laser output Po becomes minimum when the irradiation spot diameter S (S = 2w) of one laser beam is twice the dot diameter D (D = 2x) of the information image to be transferred.

Note that the above-mentioned basic formula is based on the fact that the ink layer of the thermal transfer film 13 melts at about 70°C, so the temperature of the outer periphery of the dot of the information image to be transferred is raised to about 70°C, so that the dot has a desired diameter. This was derived based on the fact that the driver 1- is transferred.

Furthermore, the present invention can be applied 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. I can do it. The hologram scanner 23 is
Holograms, which are deflection elements, are arranged on a disk substrate 24. Laser light from a laser light source (not shown) passes through a cylindrical lens 25, is reflected by a plane mirror 26, enters one of the holograms, and is emitted from the hologram. After the diffracted light is reflected by the plane mirror 27, f
The light is focused into a spot through the θ lens 2B and the cylindrical lens 29.

Furthermore, as a light source, a semiconductor laser as mentioned above, '
/AG laser, carbon dioxide laser, helium-neon laser, argon ion laser, helium-cadmium laser, etc. can also be used. In this case, as shown in FIG. 6, the laser beam emitted from the laser 31 passes through the beam compressor 32, AO modulator 33, beam expander 34, and cylindrical lens 35, and is deflected by the rotating polygon TFT 36. Rear 2 The light is irradiated onto the recording material 39 through the toroidal lens 37 and the fθ lens 38.

(Effects) As described above, in the laser thermal transfer recording device 1 according to the present invention, the laser beam irradiation spot diameter is set to approximately twice the dot diameter of the information image to be transferred, so that the laser energy can be reduced. A compact and low-cost laser thermal transfer recording device that can operate most efficiently can be obtained. In particular, it is possible to realize a device using a low-output semiconductor laser.

[Brief explanation of drawings]

1 and 2 are perspective views of a recording device according to an embodiment of the present invention, FIG. 3 is an enlarged principle view showing a laser beam irradiation spot and recording dots, and FIGS. 4, 5, and 6 The figure is a perspective view showing an example of application to other optical systems.
The figure is a perspective view of a general laser thermal transfer recording device. 11... Recording paper, 12... Platen, 1
3...Thermal transfer film, 14.31...Laser, 15...Collimator lens, 16.36...
Rotating polygon mirror, 17.28.38...fθ lens,
18.25.29.35... Cylindrical lens, 19... Heater, 23... Hologram scanner, 24... Disk, 26.27... Plane mirror, 32... Beam compressor, 33...A
O modulator, 34... Beam expander, 37...
...Toroidal lens. 39...Recording material. Pre-Z dust

Claims (1)

[Claims] A thermal transfer film is brought into close contact with a recording paper and transported by winding, and a laser beam is irradiated onto the thermal transfer film so as to be focused to a predetermined spot diameter to transfer an information image of a predetermined dot diameter onto the recording paper. A laser thermal transfer recording apparatus characterized in that the irradiation spot diameter of the laser beam is set to be approximately twice the dot diameter of the information image to be transferred.