JP2009172801A - Non-contact optical writing erasing device and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To sufficiently obtain the performance of erasing without separately providing an erasing device such as an erasing bar and also remarkably changing operating conditions in recording and erasing, e.g., by defocusing a laser beam. <P>SOLUTION: When information written in the surface of a heat-sensitive recording medium 1 is erased, the conditions in the beam diameter of a laser beam L, the power of the laser beam L and the conveying speed of the heat-sensitive recording medium 1 are made the same as those of the beam diameter of the laser beam L and the power of the laser beam L scanned onto the heat-sensitive recording medium 1 and the conveying speed of the heat-sensitive recording medium 1 upon writing, and the scanning speed of the laser beam L is made high under such conditions. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a non-contact optical writing / erasing apparatus and method using a rewritable thermosensitive recording medium that enables writing and erasing of information in a non-contact manner without directly contacting a heating device such as a thermal head.

  There are thermal writing methods using leuco dye-based and diazo compound-based thermal materials. There are reversible thermosensitive recording papers that can repeat color development and color erasing at a specific temperature. The heat-sensitive recording paper is heated and colored by a heating device such as a thermal head, for example, to be colored or decolored. As a recording method for such a thermal recording paper, for example, there is a method in which a recording head such as a thermal head is brought into direct contact with the thermal recording paper.

  On the other hand, there are, for example, Patent Documents 1 and 2 as information writing techniques using thermal recording paper. Patent Document 1 relates to a method for developing and erasing a reversible thermosensitive material in a non-contact manner, and discloses an information recording medium in which an infrared absorbing layer that absorbs infrared rays and generates heat and a thermal recording layer are sequentially laminated on a substrate. To do. Of these, the thermosensitive recording layer comprises a thermosensitive coloring layer or a metal thin film layer. This heat-sensitive recording layer is removed by color development, discoloration or melting by the heat of the infrared absorption layer. Patent Document 1 discloses a recording method in which an infrared absorption layer is heated by irradiation with an infrared laser, and the heat-sensitive recording layer is colored, discolored, or melted and removed by this heat.

  This Patent Document 1 requires a high-power laser as a light source that outputs an infrared laser. For this reason, even if a small and relatively inexpensive semiconductor laser is applied in Patent Document 1, this semiconductor laser has a limit of several W class and cannot actually realize the recording speed of the line type thermal head class. There is a method using, for example, a YAG laser having an output of several tens of W or more. However, when a YAG laser or the like is used, it is more expensive than a semiconductor laser and the apparatus becomes large.

  Patent Document 2 relates to a laser beam recording apparatus that performs image recording (writing) on a heat mode recording material, and first and second semiconductors that emit a laser beam having an elliptical cross section that extends in a direction perpendicular to the pn junction surface. A laser, a deflection beam splitter that synthesizes laser beams emitted from these semiconductor lasers, and a scanning optical system that scans the laser beam synthesized by the deflection beam splitter are provided. This Patent Document 2 combines a laser beam emitted from a first semiconductor laser and a laser beam emitted from a second semiconductor laser, and the center of the synthesized laser beam is a cross section of one of the laser beams. The semiconductor laser is arranged so as to be shifted to one end side in the major axis direction in the shape. In Patent Document 2, the main scanning is performed by the scanning optical system in a state in which the center of the combined laser beam is positioned rearward along the traveling direction along the major axis direction in the cross-sectional shape of one of the laser beams. To disclose.

On the other hand, there is an erasing device that erases information written on a thermal recording paper. As this erasing device, for example, there is a method using a linear heating element (also referred to as an erasing bar) such as a thermal head, or a method using a laser writing type printing device for erasing. A method in which a laser writing type printing apparatus is also used for erasing is mainly employed in, for example, a two-dimensional vector scanning method. In this laser writing type printing apparatus, the position of the laser beam irradiated on the thermal recording paper is changed between writing and erasing, and the laser beam is defocused and enlarged on the thermal recording paper, so that the unevenness of sweeping and writing A method of absorbing a laser beam position error at the time of erasing is employed.
Japanese Patent No. 3266922 Japanese Patent No. 2561098

  When paying attention to the technology for erasing the information written on the thermal recording paper, the recording head such as a thermal head or the erasing bar as the erasing device is in direct contact with the thermal recording paper. For example, the recording head or the erasing bar is likely to be worn or stained due to contact with the paper. Further, the print surface of the thermal recording paper is rubbed and soiled. The life of the recording head and the erasing bar is shortened due to a short circuit due to an adhering matter and excessive power supply. This leads to shortening of the service life due to scratches and wear due to the thermal recording paper itself contacting the recording head and erasing bar.

  In the method of using a laser writing type printing apparatus for erasing as well, the position of the laser beam irradiated on the thermal recording paper is changed between writing and erasing, and the laser beam is defocused on the thermal recording paper so that the laser beam is irradiated. The irradiation area is enlarged and the area to be erased is expanded. Thus, sweeping unevenness and laser beam position error during writing and erasing are absorbed. This erasing method is used because, for example, when information written by the two-dimensional vector scan method is erased by the vector scan method, it is difficult to accurately align the recording position on the thermal recording paper two-dimensionally. . In such an erasing method, as a technique for defocusing the laser beam and enlarging the irradiation area, for example, a thermal recording paper or a writing / erasing mechanism is moved to change the optical path length of the laser beam. For this reason, the mechanism for moving the thermal recording paper or the writing / erasing mechanism is complicated, and the erasing performance depends on the position error of the laser beam between writing and erasing, etc. It was not enough.

  An object of the present invention is to eliminate the need for a separate erasing device such as an erasing bar, and to improve the erasing performance without greatly changing the operating conditions at the time of writing and erasing such as defocusing the laser beam. It is an object of the present invention to provide a contactless optical writing / erasing apparatus and method that can be obtained sufficiently.

  The non-contact optical writing / erasing apparatus according to the main aspect of the present invention develops color when heated to a color development temperature higher than room temperature, and erases when heated to a color erase temperature lower than the color development temperature while maintaining the color development state at room temperature. In a non-contact optical writing / erasing apparatus that transports a thermal recording medium and scans a laser beam on the thermal recording medium being transported to write information on the thermal recording medium, the thermal recording medium is recorded on the thermal recording medium. When erasing information, the scanning speed of the laser beam scanned onto the thermal recording medium is set faster than the scanning speed of the laser beam during writing, and the energy density when scanning the laser beam onto the thermal recording medium is recorded thermally. An erasing control unit is provided for controlling the energy density necessary for heating the medium to the erasing temperature.

  The non-contact optical writing and erasing method according to another main aspect of the present invention develops color when heated to a coloring temperature higher than room temperature, and erases when heated to an erasing temperature lower than the coloring temperature while maintaining the colored state at room temperature. In a non-contact optical writing / erasing method in which a thermal recording medium to be colored is conveyed and a laser beam is scanned on the conveyed thermal recording medium to write information on the thermal recording medium, writing on the thermal recording medium is performed. When the recorded information is erased, the scanning speed of the laser beam scanned onto the thermal recording medium is set to be faster than the scanning speed of the laser beam during writing, and the energy density when the laser beam is scanned onto the thermal recording medium is set. The energy density required to heat the thermal recording medium to the decoloring temperature is controlled.

  According to the present invention, it is not necessary to separately provide an erasing device such as an erasing bar, and the erasing performance is improved without significantly changing the operating conditions at the time of writing and erasing such as defocusing the laser beam. It is possible to provide a non-contact optical writing / erasing apparatus and method that can be obtained sufficiently.

Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a configuration diagram of a non-contact optical writing / erasing apparatus. The apparatus includes a semiconductor laser (LD) 2 as a laser light source that emits a laser beam that irradiates the thermal recording medium 1. This semiconductor laser 2 has an emission wavelength in the near infrared region, for example, 750 nm to 1000 nm, and outputs a high-power laser beam of about several W. This semiconductor laser 2 has the same characteristics as a low-power semiconductor laser (laser diode: LD) already used in many laser printers, laser pointers, DVD players, etc., that is, spread angle, output-current characteristics, and temperature characteristics. Have. The semiconductor laser 2 has a large laser beam output. As a result, the semiconductor laser 2 requires cooling because the supply current amount is large in the ampere class and the heat generation amount is large. Accordingly, the semiconductor laser 2 is fixed to the heat sink and forcibly cools the heat sink.

A collimator lens 3 and a deflection scanning mechanism 4 are provided between the semiconductor laser 2 and the thermal recording medium 1 along a laser beam irradiation optical path between the semiconductor laser 2 and the thermal recording medium 1. . Among these, the collimator lens 3 is provided on the traveling optical path of the laser beam L ₁ output from the semiconductor laser 2. The collimator lens 3 condenses the laser beam L output from the semiconductor laser 2 at a substantially parallel light velocity.
The deflection scanning mechanism 4 includes a galvanometer mirror 5 and a rotation driving unit 6 as scanning mirrors. A galvanometer mirror 5 is connected to the rotation drive unit 6 via a rotation shaft 7. The rotation drive unit 6 swings the galvanometer mirror 5 back and forth in the direction of arrow a via the rotation shaft 7. Hereinafter, the reciprocating operation of the galvanometer mirror 5 in the direction of arrow a is referred to as a scanning operation.

  This will be specifically described below. As shown in FIG. 2, the semiconductor laser 2 is provided with a laser light emitting unit 10 that outputs a laser beam L. A pn junction surface 11 which is a junction surface of the active layer is formed in the laser light emitting unit 10. In the semiconductor laser 2, the junction surface direction of the pn junction surface 11 of the laser light emitting unit 10 is arranged in a direction perpendicular to the rotation axis 7 of the galvano mirror 5 in the deflection scanning mechanism 4. The deflection direction d of the laser beam L is the same direction as the junction surface direction of the pn junction surface 11. The laser beam L emitted from the laser emitting unit 10 spreads with a profile Pf as shown in FIG. 1 as it travels. The beam profile Pf has a Gaussian distribution.

  The deflection scanning mechanism 4 reciprocally scans the laser beam L condensed into a substantially parallel light beam by the collimator lens 3 in the main scanning directions Sm1 and Sm2 on the thermal recording medium 1 by the rotation of the galvanometer mirror 5 in the direction of arrow a. To do. Sm1 is the forward path in the main scanning direction, and Sm2 is the backward path in the main scanning direction. FIG. 3 shows a beam profile Bp of the laser beam L scanned on the thermal recording medium 1. This laser beam L is formed as a circular beam profile Bp on the thermal recording medium 1. As a result, the beam profile Bp is formed in a substantially circular shape, for example, with the beam diameters e1 and e2 in the vertical and horizontal directions both about 100 μm.

The thermal recording medium 1 is a rewritable and reversible medium that repeats color development and decoloring by heating control at a specific temperature to enable thermal recording and thermal erasure. As shown in FIG. 4, when the melting point of 180 ° C. or higher is applied, the heat-sensitive recording medium 1 is in a state where the dye existing in the print layer and the developer are melted together. By rapidly cooling from this state, the dye and the developer are developed. Crystallizes and develops color while mixing with the agent. On the other hand, when the thermal recording medium 1 is slowly cooled, the dye and the developer are crystallized. As a result, the heat-sensitive recording medium 1 is not in a colored state and is in a decolored state. Furthermore, when the heat-sensitive recording medium 1 is heated for a certain time which is a temperature equal to or lower than the melting point of the dye and the developer, the dye and the developer are gradually separated and crystallized to be in a decolored state. The temperature of the decoloring region is, for example, about 130 ° C. to 180 ° C. Accordingly, the heat-sensitive recording medium 1 is heated when it is heated from room temperature Tr (for example, 25 ° C.) to a color development temperature T ₂ (for example, 180 ° C.), and then rapidly cooled to develop color. In order to erase this color, the temperature is once heated from the room temperature Tr to a color erase temperature T ₁ (for example, 130 ° C.) which is lower than the color development temperature T ₂ , and if the color is cooled, the color is erased.
The transport mechanism 12 transports the thermal recording medium 1 in the same direction as the sub-scanning direction Ss, for example, at a constant transport speed. The sub-scanning direction Ss is a direction perpendicular to the main scanning directions Sm1 and Sm2. The transport mechanism 12, that is, the transport mechanism 12 continuously transports the thermal recording medium 1 while maintaining a preset transport speed.

When erasing information written on the thermal recording medium 1, the erasing control unit 13 sets the scanning speed of the laser beam L scanned on the thermal recording medium 1 from the scanning speed of the laser beam L when writing information. Thus, the energy density when the laser beam L is scanned onto the thermal recording medium 1 is controlled to an energy density necessary for heating the thermal recording medium 1 to the decoloring temperature.
In this case, the erasing control unit 13 sets the beam diameter of the laser beam L scanned on the thermal recording medium 1 at the time of erasing, the power of the laser beam L, and the conveyance speed of the thermal recording medium 1 on the thermal recording medium 1 at the time of writing. The beam diameter of the laser beam L to be scanned, the power of the laser beam L, and the conveyance speed of the thermal recording medium 1 are set to the same conditions, and the scanning speed of the laser beam L on the thermal recording medium 1 is set fast under these conditions.

  Specifically, the erasing control unit 13 controls the rotation driving unit 6 in the deflection scanning mechanism 4 at the time of erasing, and sets the scanning speed of the laser beam L in the main scanning directions Sm1 and Sm2 at the time of erasing to the laser beam at the time of writing. The scanning speed in the main scanning direction Sm1, Sm2 of L is made faster. The scanning speed of the laser beam L at this time is set as follows, for example. During normal information writing, the semiconductor laser 2 outputs a laser beam L with a constant laser power, and turns on / off the output of the laser beam L according to information such as print data. The scanning speed of the galvanometer mirror 5 is constant, and the conveyance speed of the thermal recording medium 1 by the conveyance mechanism 12 is set in accordance with the scanning speed of the galvanometer mirror 5. The beam diameter of the laser beam L output from the semiconductor laser 2, the power of the laser beam L, and the conveyance speed of the thermal recording medium 1 are set according to the resolution of information written on the thermal recording medium 1.

On the other hand, when the scanning speed of the laser beam L is increased during erasing, the energy per unit area of the laser beam L irradiated onto the thermal recording medium 1 is reduced. That is, the product of the power of the laser beam L and the irradiation time becomes small. Therefore, when erasing, the laser beam L is irradiated to irradiate the thermal recording medium 1 to a temperature of the color erasing region, for example, about 130 ° C. to 180 ° C., depending on the output power of the semiconductor laser 2. Scan speed is set. The scanning speed of the galvanometer mirror 5 at the time of erasing is set to, for example, twice the scanning speed of the galvanometer mirror 5 at the time of writing.
The semiconductor laser 2 is provided on the mount 14.

Next, writing and erasing operations by the apparatus configured as described above will be described.
At the time of writing, the semiconductor laser 2 outputs a laser beam L. The semiconductor laser 2 outputs a laser beam L with a constant laser power, and turns on / off the output of the laser beam L according to information such as print data. This laser beam L has a deflection direction d that is the same as the direction of the junction surface of the pn junction surface 11. The laser beam L is condensed at a substantially parallel light velocity by the collimator lens 3 and enters the deflection scanning mechanism 4.
The deflection scanning mechanism 4 scans the galvanometer mirror 5 via the rotation shaft 7 by the rotation drive of the rotation drive unit 6. The laser beam L condensed into a substantially parallel light beam by the collimator lens 3 by the scanning operation of the galvanometer mirror 5 is reciprocally scanned in the main scanning directions Sm1 and Sm2 on the thermal recording medium 1. The laser beam L reciprocally scanned on the thermal recording medium 1 is formed as a circular beam profile Bp as shown in FIG. The beam profile Bp is formed in a substantially circular shape, for example, with the beam diameters e1 and e2 in the vertical and horizontal directions both being about 100 μm.

On the other hand, the transport mechanism 12 transports the thermal recording medium 1 in the same direction as the sub-scanning direction Ss, for example, at a constant transport speed.
However, on the thermal recording medium 1, for example, as shown in FIG. 5, a laser beam L formed in a circular beam profile Bp is reciprocally scanned in the main scanning directions Sm1 and Sm2. As described above, when the laser beam L is reciprocally scanned in the main scanning directions Sm1 and Sm2 on the surface of the thermal recording medium 1, the temperature on the surface of the thermal recording medium 1 at this time is heated to the coloring temperature. Thereby, information can be recorded on the thermal recording medium 1. Therefore, for example, when the output of the laser beam L is turned on / off according to information such as characters, symbols, and patterns, information such as characters, symbols, and patterns can be recorded on the thermal recording medium 1. The heat-sensitive recording medium 1 is not limited to black and can be colored in any color using a dyeing material.

  On the other hand, at the time of erasing, the semiconductor laser 2 outputs a laser beam L. The semiconductor laser 2 outputs a laser beam L with a constant laser power. The laser beam L is condensed at a substantially parallel light velocity by the collimator lens 3 and enters the deflection scanning mechanism 4. In the semiconductor laser 2, the output of the laser beam L is turned on / off according to information such as characters, symbols, and patterns.

  At the time of erasing, the erasing control unit 13 scans the beam diameter of the laser beam L scanned on the thermal recording medium 1, the power of the laser beam L, and the conveyance speed of the thermal recording medium 1 onto the thermal recording medium 1 at the time of writing. Under the same conditions as the beam diameter of the laser beam L, the power of the laser beam L, and the conveyance speed of the thermal recording medium 1, the rotational driving unit 6 in the deflection scanning mechanism 4 is driven and controlled under this condition by the scanning operation of the galvanometer mirror 5. The scanning speed is set faster than the scanning speed by the scanning operation of the galvanometer mirror 5 at the time of writing, for example, twice.

  In a state where the scanning speed of the galvanometer mirror 5 is set to, for example, double, the deflection scanning mechanism 4 scans the galvanometer mirror 5 via the rotation shaft 7 by the rotation drive of the rotation drive unit 6. Thereby, the scanning speed of the laser beam L in the main scanning directions Sm1 and Sm2 on the thermal recording medium 1 at the time of erasing is, for example, 2 higher than the scanning speed of the laser beam L in the main scanning directions Sm1 and Sm2 at the time of writing. Twice as fast.

  The laser beam L condensed into a substantially parallel light beam by the collimator lens 3 by the scanning operation of the galvanometer mirror 5 reciprocates in the main scanning directions Sm1 and Sm2 on the thermosensitive recording medium 1 at a speed twice as fast as writing, for example. Scanned. At this time, the laser beam L reciprocally scanned on the thermal recording medium 1 is formed as a circular beam profile Bp as shown in FIG. Note that the galvanometer mirror 5 continuously scans the laser beam L back and forth while maintaining a preset scanning speed.

  On the other hand, the transport mechanism 12 continuously transports the thermal recording medium 1 in the same direction as the sub-scanning direction Ss, for example, maintaining a constant transport speed.

  However, on the thermal recording medium 1, for example, as shown in FIG. 5, a laser beam L formed in a circular beam profile Bp is reciprocally scanned in the main scanning directions Sm1 and Sm2 at a scanning speed, for example, twice that at the time of writing. Is done. Since the beam diameter of the laser beam L, the power of the laser beam L, and the conveyance speed of the thermal recording medium 1 at the time of erasing are set to the same conditions as those at the time of writing, the scan line of the laser beam L on the thermal recording medium 1 is set. The number increases, for example, twice as much as when writing. The laser beam L overlaps on the thermal recording medium 1 and is scanned back and forth. Since the laser beam L is reciprocally scanned at a scanning speed twice that of writing, for example, a half region of the circular beam profile Bp of the laser beam L overlaps each other (overlap). 1 is scanned back and forth. The direction in which the regions of the laser beam L overlap is the same as the direction in which the thermal recording medium 1 is transported by the transport mechanism 12.

Thus, when the scanning speed of the laser beam L is increased, the energy per unit area of the laser beam L irradiated onto the thermal recording medium 1 is reduced. That is, the product of the power of the laser beam L and the irradiation time becomes small. For example, by irradiating the laser beam L, the thermosensitive recording medium 1 is brought to the temperature of the color erasing region, for example, about 130 to 180 ° C.
Thus, when the laser beam L is reciprocally scanned on the surface of the thermal recording medium 1 at a scanning speed, for example, twice that of writing, the temperature on the surface of the thermal recording medium 1 at this time is the temperature of the decolored area. The information written in the thermal recording medium 1 is erased.

  As described above, according to the first embodiment, when information written on the thermal recording medium 1 is erased, the beam diameter of the laser beam L, the power of the laser beam L, and the conveyance speed of the thermal recording medium 1 are determined. Are the same as the beam diameter of the laser beam L, the power of the laser beam L, and the conveying speed of the thermal recording medium 1 at the time of writing, and the scanning speed of the laser beam L is increased under these conditions. To do. Thereby, the energy density when the laser beam L is scanned onto the thermal recording medium 1 can be set to an energy density necessary for heating the thermal recording medium 1 to the decoloring temperature. As a result, the information written on the thermal recording medium 1 can be erased only by increasing the scanning speed of the laser beam L.

Since the laser beam L is reciprocally scanned at a scanning speed twice as high as that at the time of writing, for example, a half region of the circular beam profile Bp of the laser beam L is in the same direction as the conveyance direction of the thermal recording medium 1. Reciprocal scanning is performed on the thermal recording medium 1 so as to overlap each other. As a result, the overlapping region of the laser beam L on the thermal recording medium 1 increases, and therefore, due to unevenness in sweeping, erasure residue caused by the position error of the laser beam L between writing and erasing, and conveyance of the thermal recording medium 1. It is possible to reduce the erasure residue caused by the position error of the laser beam L at the time of writing and erasing.
Since only the scanning speed of the laser beam L needs to be set fast, the beam diameter of the laser beam L, the power of the laser beam L and the conveyance speed of the thermal recording medium 1 at the time of writing and erasing, and further, the semiconductor laser 2 is turned on, It is only necessary to set OFF to the same condition, which can be realized with a simple change. Further, it is not necessary to provide a separate erasing device.

Next, a second embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 6 shows a configuration diagram of a non-contact optical writing / erasing apparatus. Similar to the semiconductor laser 2, the present apparatus includes a single mode semiconductor laser 20 and a multimode semiconductor laser 21. These semiconductor lasers 20 and 21 each have an emission wavelength in the near infrared region, for example, 750 nm to 1000 nm, and output high-power laser beams L ₁ and L ₂ of about several W. These semiconductor lasers 20 and 21 have the same characteristics as low-power semiconductor lasers (laser diodes: LD) already used in a large number of laser printers, laser pointers, DVD players, etc., that is, spread angle, output-current characteristics, temperature. Has characteristics. These semiconductor lasers 20 and 21 have a large laser beam output. As a result, the semiconductor lasers 20 and 21 require cooling because the supply current amount is large in the ampere class and the heat generation amount is large. Accordingly, each of the semiconductor lasers 20 and 21 is fixed to the heat sink and the heat sink is forcibly cooled.

Between the single mode semiconductor laser 20 and the thermal recording medium 1, a first collimator lens 22, a polarization beam splitter 23, a deflection scanning mechanism 24, and a scanning lens 25 are provided. Between the multimode semiconductor laser 21 and the thermal recording medium 1, a second collimator lens 26, a polarization beam splitter 23, a deflection scanning mechanism 24, and a scanning lens 25 are provided.
First collimator lens 22 condenses into a substantially parallel light flux of the single mode laser beam L ₁ output from the single mode semiconductor laser 20. Second collimator lens 26 substantially converged to parallel light flux of the multimode laser beam L ₂ output from the multimode semiconductor laser 21.

The polarization beam splitter 23 reflects the single mode laser beam L ₁ output from the single mode semiconductor laser 20 and transmits the multi mode laser beam L ₂ output from the multi mode semiconductor laser 21. and it outputs the L ₁ and the multimode laser beam L ₂ and the combined laser beam L ₃ were synthesized.
The deflection scanning mechanism 24 includes a polygon mirror 27 and a rotation drive unit 28 such as a motor, and the polygon mirror 27 is connected to the rotation drive unit 28 via a rotation shaft 29. The rotation drive unit 28 rotates the polygon mirror 27 in one direction, for example, the direction of the arrow f via the rotation shaft 29.

This will be specifically described below. Single mode semiconductor laser 20 has a laser emitting unit 30 for outputting a single mode laser beam L ₁ as shown in FIG. A pn junction surface 31 is formed in the laser light emitting unit 30. In the single mode semiconductor laser 20, the bonding surface direction of the pn bonding surface 31 of the laser light emitting unit 30 is arranged in parallel to the rotation axis of the polarizing member of the deflection scanning mechanism 24, that is, the rotation axis 29 of the polygon mirror 27.

The deflection direction Sd ₁ of the single mode laser beam L ₁ is the same direction as the junction surface direction of the pn junction surface 31. Thus, the polarization direction Sd ₁ of the single mode laser beam L ₁ is, since the direction perpendicular to the polarization beam splitter 23, the single mode laser beam L ₁ is made into S-polarized light to the polarization beam splitter 23. Accordingly, the polarization beam splitter 23 reflects the single mode laser beam L ₁ output from the single mode semiconductor laser 20.
Multimode semiconductor laser 21 has a laser emitting unit 32 for outputting a multimode laser beam L _2. The laser emission section 32 has the same configuration as the semiconductor laser 2 in the first embodiment as shown in FIG. 2 and has a pn junction surface. The multi-mode semiconductor laser 21 is arranged so that the junction surface direction of the pn junction surface of the light emitting region is perpendicular to the rotation axis of the polarizing member of the deflection scanning mechanism 24, that is, the rotation axis 29 of the polygon mirror 27. .

Polarization direction Sd ₂ of the multimode laser beam L ₂ is a cemented surface in the same direction as that of the pn junction plane. The deflection direction Sd ₂ of the multimode laser beam L ₂ is perpendicular to the rotation axis 29 of the polygon mirror 27. Since the polarization direction Sd ₂ of the multimode laser beam L ₂ output from the laser light emitting unit 15 of the multimode semiconductor laser 21 is in the horizontal direction with respect to the polarization beam splitter 23, the polarization direction is changed to P polarization with respect to the polarization beam splitter 23. Become. Therefore, the polarization beam splitter 23 is transmitted through the multimode laser beam L ₂ output from the multimode semiconductor laser 21.
Deflection scanning mechanism 24 scans the combined laser beam L ₃ output from the polarization beam splitter 23 by the rotation in the arrow f direction of the polygon mirror 27 in the main scanning direction Sm on the thermal recording medium 1. The polygon mirror 27 scans continuously laser beam L ₃ while maintaining the scanning speed set in advance. The scanning direction of the combined laser beam L ₃ is the same direction as the polarization direction Sd ₂ of the multimode laser beam L _2. Thus, the horizontal orientation of the beam profile Pf ₂ of the multimode laser beam L ₂ on the thermal recording medium 1 coincides with the main scanning direction Sm.
Scan lens 25 is provided on the scanning range in the main scanning direction Sm of the combined laser beam L ₃ by the deflection scanning mechanism 24, the deflection scanning mechanism 24 using the combined laser beam L ₃ which is the main scanning surface of the thermal recording medium 1 Condensate.

8 and 9 shows the beam profile of the single mode laser beam L ₁ and the multimode laser beam L ₂ to be focused on the thermal recording medium 1 by the scanning lens 25. The single mode laser beam L ₁ is formed as a circular beam profile Pf ₁ on the thermal recording medium 1. The multimode laser beam L ₂ is formed as a horizontally long beam profile Pf ₂ on the thermal recording medium 1. Thus, the combined laser beam L ₃ is, in the beam profile Pf ₂ of oblong, and collected on the thermal recording medium 1 in the form of repeated substantially circular beam profile Pf _1. FIG. 8 shows that a single mode laser beam L ₁ having a circular beam profile Pf ₁ is synthesized at a position behind the scanning direction Sm on the thermal recording medium 1 in a horizontally elongated beam profile Pf _{2 of the} multimode laser beam L _2. The synthesized beam profile is shown. FIG. 9 shows that a single mode laser beam L ₁ having a circular beam profile Pf ₁ is synthesized at the central position in the scanning direction Sm on the thermal recording medium 1 in the horizontally long beam profile Pf _{2 of the} multimode laser beam L _2. The synthesized beam profile is shown.

Figure 10 shows the relationship between temperature and coloring and decoloring or the like on the thermal recording medium 1 when irradiated with the single mode laser beams L ₁ and the combined laser beam L ₃ on the thermal recording medium 1. The heat-sensitive recording medium 1 is heated from a room temperature Tr (for example, 25 ° C.) to a color development temperature T ₂ (for example, 180 ° C.) and rapidly cooled to develop a color. In order to erase this color, the temperature is once heated from the room temperature Tr to a color erase temperature T ₁ (for example, 130 ° C.) which is lower than the color development temperature T ₂ , and if the color is cooled, the color is erased.
However, the single mode laser beam L ₁ has an output power capable of heating the print layer of the thermal recording medium 1 to a temperature equal to or lower than the decoloring temperature T ₁ by irradiating the thermal recording medium 1 alone. As a result, the thermal recording medium 1 does not develop color.

On the other hand, the multi-mode laser beam L ₂ alone irradiates the thermal recording medium 1 with an output power that can heat the print layer of the thermal recording medium 1 to the color erasing temperature T ₁ but not higher than the color development temperature T _2. Have. Thereby, the temperature rise at the time of irradiating the thermal recording medium 1 a multimode laser beam L ₂ alone, and the decoloring temperature above T ₁ and the color temperature T ₂ less, decolorizing the color of the thermal recording medium 1 The temperature rises to a possible erase area.

The erasure control unit 33 sets the scanning speed of the laser beam L ₃ scanned on the thermal recording medium 1 at the time of erasing to be faster than the scanning speed of the laser beam L ₃ at the time of writing, thereby causing the laser beam L ₃ to be thermally sensitive. The energy density when scanning on the recording medium 1 is controlled to an energy density necessary for heating the thermal recording medium 1 to the decoloring temperature. Erase control unit 33 at this time, the scanning beam diameter of the laser beam L ₃ to be scanned onto the thermal recording medium 1, the conveying speed of the power and the thermal recording medium 1 of the laser beam L _3, on the thermal recording medium 1 at the time of writing the beam diameter of the laser beam L ₃ which, as a conveying speed and same conditions of power and thermal recording medium 1 of the laser beam L _3, sets fast scanning speed of the laser beam L ₃ in this condition.

Specifically, at the time of erasing, the erasing control unit 33 drives and controls the rotation driving unit 28 in the deflection scanning mechanism 24 to set the scanning speed of the polygon mirror 27 faster than the scanning speed by the scanning operation of the polygon mirror 27 at the time of writing. and, faster than the scanning speed in the main scanning direction Sm1 of the laser beam L ₃ at the time of writing the scan speed in the main scanning direction Sm of the laser beam L ₃ at the time of erasing.
Scanning speed of the laser beam L ₃ is set as follows, for example. Normal information writing, for example, single mode semiconductor laser 20 outputs a laser beam L ₁ at a constant laser power, on the output of the laser beam L ₁ in accordance with information such as the print data, off. Multimode semiconductor laser 21 outputs a laser beam L ₂ at a constant laser power. The beam diameter of the laser beam L ₂ output from the multimode semiconductor laser 21 and the power of the laser beam L ₂ are set according to the resolution of information written on the thermal recording medium 1.

The scanning speed of the polygon mirror 27 is constant, and the conveyance speed of the thermal recording medium 1 by the conveyance mechanism 12 is set in accordance with the scanning speed of the polygon mirror 27. Further, the beam diameter of the laser beam L ₁ output from the single mode semiconductor laser 20, the power and the transport speed of the thermal recording medium 1 of the laser beam L ₁ is set according to the resolution of the information to be written to the thermal recording medium 1 .

Erasing the scanning speed of the laser beam L ₃ is increased, similarly to the above, the energy per unit area of the laser beam L ₃ is irradiated on the thermal recording medium 1 is reduced. Accordingly, at the time of erasing, the single mode semiconductor laser 20 and the multimode semiconductor laser 21 are arranged so that the temperature of the thermal recording medium 1 is about 130 ° C. to 180 ° C., for example, by irradiating the laser beam L _3. The scanning speed of the polygon mirror 27 is set in accordance with the output power. The scanning speed of the polygon mirror 27 at the time of erasing is set to, for example, twice the scanning speed of the polygon mirror 27 at the time of writing.
Next, writing and erasing operations by the apparatus configured as described above will be described.
At the time of writing, the single mode semiconductor laser 20 outputs an S-polarized single mode laser beam L ₁ to the polarization beam splitter 23. The single mode laser beam L ₁ is condensed by the first collimator lens 22 at a substantially parallel light velocity and enters the polarization beam splitter 23. The multimode semiconductor laser 21 outputs a P-polarized multimode laser beam L ₂ to the polarization beam splitter 23. The multi-mode laser beam L ₂ is condensed by the second collimator lens 26 at a substantially parallel light velocity and enters the polarization beam splitter 23.

The polarization beam splitter 23 reflects the single mode laser beam L ₁ output from the single mode semiconductor laser 20 and transmits the multi mode laser beam L ₂ output from the multi mode semiconductor laser 21, thereby combining the combined laser beam L. ₃ is output.

The deflection scanning mechanism 24 continuously rotates the polygon mirror 27 in the direction of the arrow f via the rotation shaft 29 by driving the rotation driving unit 28. Thereby, the polygon mirror 27, main scanning of the combined laser beam L ₃ output from the polarization beam splitter 23 in the main scanning direction Sm on the thermal recording medium 1.
The scanning lens 25 condenses the combined laser beam L ₃ main scanned by the deflection scanning mechanism 24 on the surface of the thermal recording medium 1. The combined laser beam L ₃ is, for example, in FIG. 8 or the beam profile Pf ₂ oblong shape of the multimode laser beam L ₂ as shown in FIG. 9, overlapping circular beam profile Pf ₁ of the single mode laser beam L ₁ And condensed on the surface of the thermal recording medium 1.

The laser beam L ₃ of this synthesis, the surface of the thermal recording medium 1 is the main scanning in the horizontal direction and the same direction of the beam profile Pf ₂ of the multimode laser beam L _2. First, the multi-mode laser beam L ₂ included in the combined laser beam L ₃ is irradiated alone on the surface of the thermal recording medium 1. Temperature on the thermal recording medium 1 side in this case, although color temperature T ₂ less as shown in FIG. 10, rise is rapid heating to a decoloring temperature T _1.

Then, the surface of the thermal recording medium 1, and a multimode laser beam L ₂ and the single mode laser beam L ₁ is irradiated to overlap. The temperature on the surface of the thermal recording medium 1 at this time is rapidly heated from the state heated to the decoloring temperature T ₁ to the color developing temperature T ₂ and rises. Thereby, information can be recorded on the thermal recording medium 1.
Then, the irradiation of the single mode laser beams L _1, end the irradiation of the multimode laser beam L ₂ is subsequently printing layer of the thermal recording medium 1 is quickly cooled. Thus, the portion of the multimode laser beam L ₂ is the printing layer of the thermal recording medium 1 irradiated singly is originally recorded, if any portion of the colored black, is decolored. Furthermore, part of the multimode laser beam L ₂ and the single mode laser beam L ₁ and the printing layer of the thermal recording medium 1 irradiated overlap, coloring in black. Thus, for example, characters and symbols, if the on-off output of the single mode laser beam L ₁ in accordance with information such as the picture, for example, characters or symbols on the thermal recording medium 1, it becomes possible to record information such as a picture. The heat-sensitive recording medium 1 is not limited to black and can be colored in any color using a dyeing material.

On the other hand, at the time of erasing, the single mode semiconductor laser 20 outputs an S-polarized single mode laser beam L ₁ to the polarization beam splitter 23 as described above. The single mode semiconductor laser 20, the output of the laser beam L ₁ is turned on and off in accordance with example text or symbols, information such as picture. The single mode laser beam L ₁ is condensed by the first collimator lens 22 at a substantially parallel light velocity and enters the polarization beam splitter 23. On the other hand, the multimode semiconductor laser 21 in the same manner as described above, and outputs a multimode laser beam L ₂ of the P-polarized light to the polarization beam splitter 23. The multi-mode laser beam L ₂ is condensed by the second collimator lens 26 at a substantially parallel light velocity and enters the polarization beam splitter 23.

The polarization beam splitter 23 reflects the single mode laser beam L ₁ output from the single mode semiconductor laser 20 and transmits the multi mode laser beam L ₂ output from the multi mode semiconductor laser 21, thereby combining the combined laser beam L. ₃ is output.

Erasing, the erase control unit 33, the beam diameter of the laser beam L ₃ to be scanned onto the thermal recording medium 1, the conveying speed of the power and the thermal recording medium 1 of the laser beam L _3, on the thermal recording medium 1 at the time of writing the beam diameter of the laser beam L ₃ to be scanned, and the conveying speed and the same conditions of power and thermal recording medium 1 of the laser beam L _3, the scanning speed of the laser beam L ₃ to be scanned onto the thermal recording medium 1 in this condition, The scanning speed of the polygon mirror 27 is changed according to the output powers of the single mode semiconductor laser 20 and the multimode semiconductor laser 21 so that the temperature of the thermal recording medium 1 is about 130.degree. Is set. The scanning speed of the polygon mirror 27 at the time of erasing is set to, for example, twice the scanning speed of the polygon mirror 27 at the time of writing.

On the other hand, the transport mechanism 12 transports the thermal recording medium 1 in the same direction as the sub-scanning direction Ss, for example, at a constant transport speed.
However, on the thermal recording medium 1, the laser beam L ₃ is repeatedly scanned in the main scanning direction Sm in scanning speed also for example two times from the time of writing. The beam diameter of the laser beam L ₃ at the time of erasing, the power of the laser beam L ₃ , and the conveyance speed of the thermal recording medium 1 are set to the same conditions as those at the time of writing, so the laser beam L ₃ on the thermal recording medium 1 is set. The number of scan lines increases by a factor of two, for example, compared to writing. Since the laser beam L ₃ is reciprocally scanned at a scanning speed that is twice as high as that at the time of writing, for example, the regions of the laser beam L ₃ overlap each other and are scanned onto the thermal recording medium 1. Direction in which the region of the laser beam L ₃ is overlap, the thermal recording medium 1 is the same direction as the direction which is transported by the transport mechanism 12.

As described above, when the scanning speed of the laser beam L ₃ is increased, the energy per unit area of the laser beam L ₃ irradiated onto the thermal recording medium 1 is decreased. As a result, the temperature of the thermal recording medium 1 in the color erasing region, for example, about 130 ° C. to 180 ° C. is obtained by irradiating the laser beam L ₃ . Information written on the thermal recording medium 1 is erased.

As described above, according to the second embodiment, when erasing the information written on the thermal recording medium 1, the laser beam the beam diameter of L _3, the laser beam L ₃ power and of the thermal recording medium 1 the conveying speed, the heat-sensitive recording beam diameter of the laser beam L ₃ to be scanned on the medium 1, the conveying speed and the same conditions of power and thermal recording medium 1 of the laser beam L ₃ at the time of writing, the laser beam L ₃ in this condition Since the scanning speed is increased, the same effect as in the first embodiment can be obtained.

Next, a third embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIG. 6 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 11 shows a configuration diagram of a non-contact optical writing / erasing apparatus. The deflection scanning mechanism 40 includes a galvanometer mirror 41 and a rotation drive unit 43. A galvanometer mirror 41 is connected to the rotation drive unit 43 via a rotation shaft 42. The rotation driving unit 43 scans the galvanometer mirror 41 in the direction of arrow g via the rotation shaft 42. The rotation axis 42 of the galvanometer mirror 41 is provided in a direction parallel to the deflection direction Sd ₁ of the single mode laser beam L ₁ and perpendicular to the polarization direction Sd ₂ of the multimode laser beam L ₂ . As a result, the deflection scanning mechanism 40 scans the synthesized laser beam L ₃ output from the polarization beam splitter 23 by the scanning operation of the galvano mirror 41 in the direction of arrow g back and forth on the thermal recording medium 1. The galvanometer mirror 41 reciprocates scan continuously the laser beam L ₃ while maintaining the scanning speed set in advance. This scan is in the same direction as the polarization direction Sd ₂ of the multimode laser beam L ₂ . This scan is composed of a forward main scanning direction Sm ₁ and a backward main scanning direction Sm ₂ .

Erase control unit 44, when erasing the information written on the thermal recording medium 1, the scanning speed of the laser beam L ₃ to be scanned onto the thermal recording medium 1, the scanning speed of the laser beam L ₃ at the time of writing also set to be faster, thereby controlling the energy density when scanning the laser beam L ₃ on the thermal recording medium 1 to the energy density required to heat the thermal recording medium 1 in the decoloring temperature. Erase control unit 44 at this time, at the time of erasing, the beam diameter of the laser beam L ₃ to be scanned onto the thermal recording medium 1, the power and transport speed of the thermal recording medium 1 of the laser beam L _3, the thermal recording medium 1 at the time of writing the beam diameter of the laser beam L ₃ to be scanned above the conveying speed and the same conditions of power and thermal recording medium 1 of the laser beam L _3, sets fast scanning speed of the laser beam L ₃ in this condition.

Specifically, at the time of erasing, the erasing control unit 44 drives and controls the rotation driving unit 43 in the deflection scanning mechanism 40 to set the scanning speed of the galvano mirror 41 faster than the scanning speed by the scanning operation of the galvano mirror 41 at the time of writing. Then, the scanning speed of the laser beam L _{3 in} the main scanning directions Sm ₁ and Sm ₂ at the time of erasing is set higher than the scanning speed of the laser beam L in the main scanning directions Sm ₁ and Sm ₂ at the time of writing.
Scanning speed of the laser beam L ₃ is set as follows, for example. Normal write, for example, single mode semiconductor laser 20 outputs a laser beam L ₁ at a constant laser power, on the output of the laser beam L ₁ in accordance with information such as the print data, off. The scanning speed of the galvanometer mirror 41 is constant, and the conveyance speed of the thermal recording medium 1 by the conveyance mechanism 12 is set in accordance with the scanning speed of the galvanometer mirror 41. Further, the beam diameter of the laser beam L ₁ output from the single mode semiconductor laser 20, the power and the transport speed of the thermal recording medium 1 of the laser beam L ₁ is set according to the resolution of the information to be written to the thermal recording medium 1 .

Erasing the scanning speed of the laser beam L ₃ is increased, similarly to the above, the energy per unit area of the laser beam L ₃ is irradiated on the thermal recording medium 1 is reduced. Accordingly, at the time of erasing, the single mode semiconductor laser 20 and the multimode semiconductor laser 21 are arranged so that the temperature of the thermal recording medium 1 is about 130 ° C. to 180 ° C., for example, by irradiating the laser beam L _3. The scanning speed of the galvanometer mirror 41 is set in accordance with the output power of. The scanning speed of the galvano mirror 41 at the time of erasing is set to, for example, twice the scanning speed of the galvano mirror 41 at the time of writing.

Next, writing and erasing operations by the apparatus configured as described above will be described.
At the time of writing, the single mode laser beam L ₁ output from the single mode semiconductor laser 20 and the multi mode laser beam L ₂ output from the multi mode semiconductor laser 21 are incident on the polarization beam splitter 23 in the same manner as described above. output from the polarization beam splitter 23 as the laser beam L ₃ of the synthesis.

The deflection scanning mechanism 40 scans the galvanometer mirror 41 via the rotation shaft 42 by the rotation driving of the rotation driving unit 43. The laser beam L ₃ by the scanning operation of the galvano mirror 41 is reciprocally scanned in the main scanning direction Sm1, Sm2 on the thermal recording medium 1. The combined laser beam L ₃ is, for example, the multimode laser beam beam profile Pf ₂ of L ₂ of oblong shape, as shown in FIG. 8 or FIG. 9, the circular beam profile Pf ₁ of the single mode laser beam L ₁ The light is condensed and condensed on the surface of the thermal recording medium 1. The combined laser beam L ₃ is the surface of the thermal recording medium 1 is the main scanning in the horizontal direction and the same direction of the beam profile Pf ₂ of the multimode laser beam L _2.

On the other hand, the transport mechanism 12 transports the thermal recording medium 1 in the same direction as the sub-scanning direction Ss, for example, at a constant transport speed. Thereby, the synthetic laser beam L ₃ is scanned over the entire surface of the thermal recording medium 1. As a result, information is recorded on the thermal recording medium 1. Since the operation when information is recorded on the thermal recording medium 1 is the same as that of the second embodiment, the description thereof is omitted here.

On the other hand, at the time of erasing, the single mode semiconductor laser 20 outputs an S-polarized single mode laser beam L ₁ to the polarization beam splitter 23 as described above. The single mode semiconductor laser 20, the output of the laser beam L ₁ is turned on and off in accordance with example text or symbols, information such as picture. The single mode laser beam L ₁ is condensed by the first collimator lens 22 at a substantially parallel light velocity and enters the polarization beam splitter 23. On the other hand, the multimode semiconductor laser 21 in the same manner as described above, and outputs a multimode laser beam L ₂ of the P-polarized light to the polarization beam splitter 23. The multi-mode laser beam L ₂ is condensed by the second collimator lens 26 at a substantially parallel light velocity and enters the polarization beam splitter 23.

The polarization beam splitter 23 reflects the single mode laser beam L ₁ output from the single mode semiconductor laser 20 and transmits the multi mode laser beam L ₂ output from the multi mode semiconductor laser 21, thereby combining the combined laser beam L. ₃ is output.

Erasing, the erase control unit 44, the beam diameter of the laser beam L ₃ to be scanned onto the thermal recording medium 1, the conveying speed of the power and the thermal recording medium 1 of the laser beam L _3, on the thermal recording medium 1 at the time of writing the beam diameter of the laser beam L ₃ to be scanned, and the conveying speed and the same conditions of power and thermal recording medium 1 of the laser beam L _3, the scanning speed of the laser beam L ₃ to be scanned onto the thermal recording medium 1 in this condition, The scanning speed of the polygon mirror 27 is set in accordance with the output power of the semiconductor laser 2 so that the temperature of the thermal recording medium 1 is in the decolored region, for example, about 130 ° C. to 180 ° C. For example, the scanning speed of the galvano mirror 41 is set to, for example, twice the scanning speed of the galvano mirror 41 at the time of writing.

On the other hand, the transport mechanism 12 transports the thermal recording medium 1 in the same direction as the sub-scanning direction Ss, for example, at a constant transport speed.
However, on the thermal recording medium 1, the laser beam L ₃ is repeatedly scanned in the main scanning direction Sm in scanning speed also for example two times from the time of writing. The beam diameter of the laser beam L ₃ at the time of erasing, the power of the laser beam L ₃ , and the conveyance speed of the thermal recording medium 1 are set to the same conditions as those at the time of writing, so the laser beam L ₃ on the thermal recording medium 1 is set. The number of scan lines increases by a factor of two, for example, compared to writing. Since the laser beam L ₃ is reciprocally scanned at a scanning speed that is twice as high as that at the time of writing, for example, the regions of the laser beam L ₃ overlap each other and are scanned onto the thermal recording medium 1. Direction in which the region of the laser beam L ₃ is overlap, the thermal recording medium 1 is the same direction as the direction which is transported by the transport mechanism 12.

As described above, when the scanning speed of the laser beam L ₃ is increased, the energy per unit area of the laser beam L ₃ irradiated onto the thermal recording medium 1 is decreased. As a result, the temperature of the thermal recording medium 1 in the color erasing region, for example, about 130 ° C. to 180 ° C. is obtained by irradiating the laser beam L ₃ . Information written on the thermal recording medium 1 is erased.

As described above, according to the third embodiment, when erasing the information written on the thermal recording medium 1, the laser beam the beam diameter of L _3, the laser beam L ₃ power and of the thermal recording medium 1 the conveying speed, the heat-sensitive recording beam diameter of the laser beam L ₃ to be scanned on the medium 1, the conveying speed and the same conditions of power and thermal recording medium 1 of the laser beam L ₃ at the time of writing, the laser beam L ₃ in this condition Since the scanning speed is increased, the same effect as in the first embodiment can be obtained.

Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.
For example, in each of the above embodiments, the scanning speed of the laser beam L or the like at the time of erasing is set to, for example, twice as high as the scanning speed at the time of writing. The scanning speed of the laser beam L or the like at the time of erasing may be set to any scanning speed as long as it can be heated to a temperature of approximately 130 ° C. to 180 ° C., for example.

The laser beam to be scanned on the thermal recording medium 1 is one of the laser beam L, or is a laser beam L ₁ and the laser beam L ₃ of the laser beam L ₂ was synthesized, not limited thereto, three A combination of the above laser beams may be used.

The block diagram which shows 1st Embodiment of the non-contact optical writing erasing apparatus based on this invention. The block diagram which shows the laser light emission part provided in the semiconductor laser in the apparatus. The figure which shows the beam profile of the laser beam scanned on the thermal recording medium used for the apparatus. The figure which shows the recording / erasing characteristic of the thermosensitive recording medium used for the apparatus. The figure which shows the scan of the laser beam at the time of the writing in the same apparatus, and the deletion. The block diagram which shows 2nd Embodiment of the non-contact optical writing erasing apparatus based on this invention. The block diagram which shows the laser light emission part provided in the multimode semiconductor laser in the apparatus. The figure which shows the beam profile of the single mode laser beam condensed on the thermal recording medium in the same apparatus, and a multimode laser beam. The figure which shows the beam profile of the single mode laser beam condensed on the thermal recording medium in the same apparatus, and a multimode laser beam. The figure which shows the relationship between the temperature on a thermal recording medium, color development, decoloring, etc. when a thermal recording medium is irradiated with the single mode laser beam and the synthetic | combination laser beam in the apparatus. The block diagram which shows 3rd Embodiment of the non-contact optical writing erasing apparatus based on this invention.

Explanation of symbols

  1: thermal recording medium, 2: semiconductor laser (LD), 3: collimator lens 22: deflection scanning mechanism, 5: galvanometer mirror, 6: rotation drive unit, 7: rotation axis, 10: laser emission unit, 11: pn junction Surface: 12: transport mechanism, 13: erasure control unit, 14: mount, 20: single mode semiconductor laser, 21: multimode semiconductor laser, 22: first collimator lens, 23: polarization beam splitter, 24: deflection scanning mechanism , 25: scanning lens, 26: second collimator lens, 27: polygon mirror, 28: rotation drive unit, 29: rotation axis, 30: laser emission unit, 31: pn junction surface, 32: laser emission unit, 33: Erase control unit, 40: deflection scanning mechanism, 41: galvanometer mirror, 42: rotation axis, 43: rotation drive unit, and 44: erase control unit.

Claims (11)

The thermosensitive recording medium that develops color when heated to a color development temperature higher than room temperature and decolors when heated to a decolorization temperature lower than the color development temperature while maintaining the color development state at room temperature, and the thermal sensitivity being conveyed. In a non-contact optical writing / erasing apparatus that scans a laser beam on a recording medium and writes information on the thermal recording medium,
When erasing the information written on the thermal recording medium, set the scanning speed of the laser beam scanned on the thermal recording medium faster than the scanning speed of the laser beam when writing the information, An erasure control unit that controls an energy density when the laser beam is scanned onto the thermal recording medium to an energy density necessary to heat the thermal recording medium to the decoloring temperature;
A non-contact optical writing / erasing apparatus comprising:   The erasing control unit sets the beam diameter of the laser beam scanned on the thermal recording medium at the time of erasing, the power of the laser beam, and the conveyance speed of the thermal recording medium on the thermal recording medium at the time of writing. 2. The non-contact optical writing / erasing apparatus according to claim 1, wherein the same conditions are used as the beam diameter of the laser beam to be scanned, the power of the laser beam, and the conveyance speed of the thermal recording medium.   The erasing control unit sets a scanning direction of the thermal recording medium between the irradiation areas of the laser beam to scan a plurality of lines on the thermal recording medium by setting the scanning speed of the laser beam fast at the time of erasing. 2. The non-contact optical writing / erasing apparatus according to claim 1, wherein overlapping portions are generated in the same direction. At least one laser light source for outputting the laser beam;
A scanning mechanism that scans the thermal recording medium with the laser beam output from the laser light source;
With
The erasure control unit controls the scanning speed of the laser beam by the scanning mechanism faster than the scanning speed of the laser beam at the time of writing during the erasing,
The non-contact optical writing / erasing apparatus according to claim 1.   5. The non-scanning mechanism according to claim 4, wherein the scanning mechanism includes a scanning mirror that scans the laser beam onto the thermal recording medium, and the scanning mirror is scanned at a high speed under the control of the erasing control unit. Contact light writing / erasing device.   6. The non-contact optical writing / erasing apparatus according to claim 5, wherein the scanning mirror includes a polygon mirror or a galvanometer mirror. The laser light source includes a first semiconductor laser on which a first bonding surface of an active layer that outputs a first semiconductor laser beam is formed, and a second bonding surface of an active layer that outputs a second semiconductor laser beam. A second semiconductor laser formed with
The scanning mechanism rotationally drives a scanning mirror that scans the laser beam on the thermal recording medium around a rotation axis,
The direction of the first bonding surface of the first semiconductor laser is provided in parallel to the rotation axis of the scanning mirror,
The direction of the second bonding surface of the second semiconductor laser is provided perpendicular to the rotation axis of the scanning mirror,
A first condensing lens for condensing the first semiconductor laser beam;
A second condenser lens for condensing the second semiconductor laser beam;
A laser beam combining element that combines and outputs the first semiconductor laser beam condensed by the first condenser lens and the second semiconductor laser beam condensed by the second condenser lens. When,
Comprising
The scanning mechanism scans the thermal recording medium with the combined laser beam output from the laser beam combining element by rotationally driving the scanning mirror about the rotation axis,
The erasing control unit controls the scanning speed of the laser beam by the scanning mechanism faster than the scanning speed of the laser beam at the time of writing during the erasing, and the laser beam irradiated onto the thermal recording medium The energy per unit area is reduced, and the temperature on the surface of the thermal recording medium is heated to the decoloring temperature.
The non-contact optical writing / erasing apparatus according to claim 4. A laser light source for outputting the laser beam;
The erasing control unit sets the beam diameter of the laser beam, the power of the laser beam, and the conveyance speed of the thermal recording medium to the same conditions at the time of erasing and at the time of writing. The scanning speed of the laser beam is set faster than the scanning speed of the laser beam at the time of writing, and the laser light source is turned on / off in the same manner as the on / off control at the time of writing.
The non-contact optical writing / erasing apparatus according to claim 1. The thermosensitive recording medium that develops color when heated to a color development temperature higher than room temperature and decolors when heated to a decolorization temperature lower than the color development temperature while maintaining the color development state at room temperature, and the thermal sensitivity being conveyed. In a non-contact optical writing and erasing method for writing information on the thermal recording medium by scanning a laser beam on the recording medium,
At the time of erasing recorded on the thermal recording medium, the scanning speed of the laser beam scanned on the thermal recording medium is set faster than the scanning speed of the laser beam at the time of writing, and the laser beam is Controlling the energy density when scanned on the thermal recording medium to an energy density required to heat the thermal recording medium to the decoloring temperature;
A non-contact optical writing and erasing method.   The diameter of the laser beam scanned on the thermal recording medium at the time of erasing, the power of the laser beam, and the conveyance speed of the thermal recording medium at the time of writing are adjusted with respect to the laser beam scanned on the thermal recording medium. 10. The non-contact optical writing / erasing method according to claim 9, wherein the beam diameter, the power of the laser beam, and the conveyance speed of the thermal recording medium are the same.   By setting the scanning speed faster than the scanning speed of the laser beam at the time of erasing, an overlap portion is generated in the same direction as the conveyance direction of the thermal recording medium between the irradiation areas of the laser beam scanned on the thermal recording medium. The non-contact optical writing / erasing method according to claim 9.

Images