JP2933749B2 - Thermoreversible recording medium recording apparatus and recording method thereof - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermoreversible recording medium recording apparatus capable of repeatedly printing visual information on a card or a sheet by a thermal means such as a thermal head and a recording method thereof.

[0002]

2. Description of the Related Art Conventionally, an apparatus for recording using an exothermic recording element for image formation has features that the exothermic recording element is inexpensive, the recording process is simple, and the apparatus price can be reduced. , As a recording device. As the type, a thermal recording method of directly writing on thermal paper is known, and is applied to a facsimile or a printer.

The recording paper used in this method is disclosed in
As disclosed in JP-A-5-14039, a color-forming reaction between a colorless dye (leuco dye) as an electron donor and a developer (phenolic acid substance) as an electron acceptor is utilized, and both of them are used. It is provided with a heat-sensitive layer for assisting the reaction. When heat energy from the heating recording element of the recording device is applied to the recording paper, the colorless dye and the developer dissolve and react,
Color develops. When a difference in density occurs between the colored portion and the non-colored portion, characters and images are recorded and visually recognized.

[0004]

However, in the conventional recording apparatus, the information is recorded on a recording medium such as a card or a sheet in a visible manner, that is, printed and recorded, and the printed and recorded portion is entirely erased to reproduce the data. However, there is no device for performing new printing on the reproduced portion.

[0005] Therefore, the thermal recording paper once recorded has to be discarded when the information is no longer needed. In the information communication era such as today, the amount of the discard is enormous, and the consumption of resources is increasing. The use of recycled paper has been encouraged and increased for the purpose of saving resources, but resources are also consumed when making recycled paper.

Incidentally, a recording medium which can be used repeatedly can be printed and recorded on the recording medium in a directly visible manner, the entire printed and recorded portion is erased and reproduced, and the reproduced portion is newly printed and recorded. It would be desirable if a printing device could be developed because it would save resources.

[0007] Therefore, the present invention provides a method for printing and recording on a recording medium such as a card or a sheet in a visible manner, erasing all of the printed and recorded portions, and reproducing a new print on the reproduced portion. It is an object of the present invention to provide a printing apparatus capable of performing printing, that is, a printing apparatus and a printing method capable of repeatedly printing directly and visually on the same printing medium.

[0008]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention provides a thermoreversible recording medium recording apparatus of (1) to ( 2 ) described below and recording of the thermoreversible recording medium. A recording method using the apparatus has been invented.

[0009] (1) 1st thermoreversible recording medium recording apparatus of the present invention includes a receiving discharge portion for and discharging accept thermoreversible recording medium, constant temperature heating section for heating the thermally reversible inversion temperature range And, a cooling unit that cools the thermoreversible recording medium heated to the thermoreversible reversal temperature range to room temperature, and a thermal printing unit that prints by heating the cooled thermoreversible recording medium to a thermoreversible reversal temperature or higher. A reversing mechanism for reversing the traveling direction of the thermoreversible recording medium, and a transport unit for transporting the thermoreversible recording medium to the receiving / discharging unit, the constant temperature heating unit, the cooling unit, the reversing mechanism, the thermal printing unit, and the receiving / discharging unit. And a thermoreversible recording medium recording device.

The arrangement of the components of the recording apparatus of the first thermoreversible recording medium of the present invention is arranged in the order of a receiving / discharging section, a thermal printing section, a constant temperature heating section, a cooling section, and a reversing mechanism. The printing unit has a mechanism for moving toward and away from the transport unit, and the constant temperature heating unit has a mechanism for moving toward and away from the transport unit. This first
In the thermoreversible recording medium recording apparatus of the second aspect of the present invention, the cooling unit and the reversing mechanism are configured as an integral part, and further, an optical sensor for detecting passage of the thermoreversible recording medium in the receiving / discharging unit is provided. The cooling unit has an optical sensor that detects passage of the thermoreversible recording medium through the cooling unit.

According to the present invention, a thermoreversible recording medium is inserted into a receiving / discharging section by using the first thermoreversible recording medium recording apparatus, and the operation of the transport section is started. The print record is erased by heating to a thermoreversible reversal temperature range with a constant temperature heating unit while transporting the thermoreversible recording medium, and cooling the thermoreversible recording temperature below the thermoreversible reversal temperature range with a cooling unit while transporting the thermoreversible recording medium. Reversing the direction of travel of the medium, heating the thermoreversible reversal temperature range or more in the thermal printing section while transporting the thermoreversible recording medium, performing thermal printing, and discharging the thermoreversible recording medium from the receiving and discharging section. This is a method for recording a thermoreversible recording medium.

In the method of recording on a thermoreversible recording medium using the first thermoreversible recording medium recording device,
The operation of the transport unit is started by detecting that the thermoreversible recording medium has been inserted into the receiving and discharging unit by a sensor.

In the method of recording on a thermoreversible recording medium using the first thermoreversible recording medium recording apparatus,
The reversal of the traveling direction of the thermoreversible recording medium is performed by detecting the passage of the thermoreversible recording medium through the cooling section with a sensor.

In the method of recording on a thermoreversible recording medium using the first thermoreversible recording medium recording device,
When the thermoreversible recording medium advances on the outward path, the thermal printing section is moved to a position away from the transport path of the thermoreversible recording medium, and the constant temperature heating section is moved to a position close to the transport path of the thermoreversible recording medium. When the advance of the thermoreversible recording medium is returning, the thermal printing section is moved to a position close to the transport path of the thermoreversible recording medium, and the constant temperature heating section is moved to the transport path of the thermoreversible recording medium. It is to be moved to a remote position.

[0015] (2) a second thermoreversible recording medium recording apparatus of the present invention includes a receiving discharge portion for and discharging accept thermoreversible recording medium, functions and heat for heating the thermally reversible inversion temperature range A heating unit having a function of printing by heating the reversible recording medium at or above the thermoreversible inversion temperature, a cooling unit for cooling the thermoreversible recording medium heated to the thermoreversible inversion temperature range to room temperature, and a thermoreversible A reversing mechanism for reversing the direction of travel of the reversible recording medium, and a transport unit for transporting a transport line including the receiving / discharging unit, the heating unit, the cooling unit, and the reversing mechanism. Device.

[0016] In the second thermoreversible recording medium recording apparatus, it is assumed that the cooling unit and reversing mechanism is composed of integral parts, a light sensor for detecting passage of the thermoreversible recording medium in the receiving discharge portion The cooling unit has an optical sensor for detecting the passage of the thermoreversible recording medium.

[0017] The present invention uses the second thermoreversible recording medium recording apparatus, the thermoreversible recording medium was inserted into the receiving discharge unit starts operation of the conveyor section, thermoreversible recording medium The recording section is heated to a thermoreversible reversal temperature range by a heating section while transporting the thermoreversible recording medium. The direction of travel of the thermoreversible recording medium is reversed, and while the thermoreversible recording medium is being conveyed, it is heated to a temperature higher than the thermoreversible reversal temperature range by the same heating unit as described above, and thermal printing is performed. From a thermoreversible recording medium.

In the second method of recording on a thermoreversible recording medium using the thermoreversible recording medium recording apparatus, the operation of the thermoreversible transport unit is started by the receiving / discharging unit of the thermoreversible recording medium. Is detected by a sensor.

[0019] Using this second th thermoreversible recording medium recording apparatus, a method of recording to a thermoreversible recording medium, a reversal of the traveling direction of the thermoreversible recording medium, cooling the thermoreversible recording medium It is assumed that the passage of the section is detected by a sensor.

[0020] Using this second th thermoreversible recording medium recording apparatus, a method of recording to a thermoreversible recording medium, when the progress of the thermoreversible recording medium is forward, thermoreversible thermal printing unit Move to a position away from the recording medium transport path,
In addition, the constant temperature heating unit is moved to a position close to the transport path of the thermoreversible recording medium, and further, when the thermoreversible recording medium advances in the return path, the thermal printing unit is moved to the transport path of the thermoreversible recording medium. It should be moved to a close position, and the constant temperature heating unit should be moved to a position distant from the transport path of the thermoreversible recording medium.

FIGS. 4A and 4B show the layer structure of the thermoreversible recording medium used in the recording apparatus of the present invention.

In FIG. 4A, a thermoreversible recording layer 51 made of a thermoreversible recording material is formed on a substrate 50. A transparent protective film 52 is formed thereon. As each material of the thermoreversible recording medium, for example, the following materials can be used. As the substrate 50, a transparent plastic film such as a polyester film can be used. For the thermoreversible recording layer 51, a mixture of a saturated carboxylic acid or a derivative thereof and polyvinyl butyral is used, and is applied on the substrate 50 so as to have a film thickness of 10 to 50 μm. A protective film 52 of a transparent plastic such as a polyester film of about 1 to 10 μm is provided thereon.

FIG. 4B shows the structure of still another thermoreversible recording medium, in which a red or black colored light absorbing layer 63 or a light reflecting layer which reflects light such as a metal film is formed on a substrate 60. 63
Is formed thereon, so that the thermoreversible recording layer 61 made of a thermoreversible recording material has a thickness of 10 to 50 μm.
And a transparent protective film 62 is further formed thereon. As the materials of the thermoreversible recording medium, for example, the same materials as those used in the thermoreversible recording medium of FIG.
It may be the same as (a).

FIG. 5 shows a hysteresis curve of the temperature-light transmittance of these thermoreversible recording media. Heat the thermoreversible recording medium in the range of T ₁ 57~T ₂ 70 ℃, when returning the room temperature, the thermoreversible recording medium is fixed to an opaque state. The thermoreversible recording medium was heated at 70 ° C.
When heated to a temperature in the range of from 200 ° C. to 200 ° C., which is the melting point temperature of Slek B, it is fixed in a transparent state. Such a thermoreversible recording medium first has a temperature range T shown in FIG.
Heating is performed at a constant temperature, for example, 60 to 70 ° C., from _{1 to} T ₂ (this heating temperature range fixed to an opaque state is referred to as (A) temperature range, and also referred to as thermoreversible inversion temperature range).
(A) a thermoreversible recording medium heated to a temperature range
When the thermoreversible recording medium is cooled back to a temperature lower than the temperature range, the thermoreversible recording medium enters the opaque state B.

Next, the thermoreversible recording medium is brought into a transparent state (D) by heating to a temperature higher than the thermoreversible reversal temperature range (referred to as a temperature (C)), for example, 90 ° C. or higher, and returning to room temperature. The material in the transparent state (D) can be made opaque by further heating at a constant temperature within the temperature range A, that is, the thermoreversible inversion temperature range. By heating again to a temperature higher than the thermoreversible reversal temperature range, that is, to the temperature (C), the state again becomes transparent (D). This thermoreversible recording medium can be reproduced even with 100 or more repetitions.

This thermoreversible recording medium is in an opaque state (B)
From the transparent state (D) to the opaque state (B) in 100 milliseconds.

[0027]

According to the thermoreversible recording medium recording apparatus of the present invention, by applying two types of heating to a thermoreversible recording medium having a property that the transparency to visible light changes according to the heat history, the thermoreversible reversal temperature range or higher is obtained. Print recording by heating a pattern selected by heating and erasing by heating in a thermoreversible reversal temperature range of the printed pattern can be performed.

[0028]

Embodiment 1 FIG. 1 shows an embodiment of a thermoreversible recording medium recording apparatus of the present invention.

Reference numeral 102 denotes a receiving unit having an opening for receiving the thermoreversible recording medium 101 such as a card or a sheet into the thermoreversible recording medium recording apparatus. Reference numeral 105 denotes a takeout unit having an outlet for discharging the thermoreversible recording medium 101 from the thermoreversible recording medium recording device. A transport line for transporting the thermoreversible recording medium 101 is formed so as to connect the receiving section 102 and the take-out section 105. On this transport line, in order from the receiving unit 102 side,
A constant temperature heating unit 103, a cooling unit also serving as a capstan 109, a thermal printing unit 104, and a take-out unit 105 are arranged.

The constant temperature heating unit 103 is a heating device maintained at a constant temperature, and includes, for example, a heating plate heated to 60 to 70 ° C. or a heating roller. In addition, a cooling roller can be used as the cooling unit, and the cooling roller can be used in combination with the transfer capstan 109.
Next, the thermal printing unit 104 selectively heats the shape of characters, figures, and the like with a thermal head or the like at a temperature not lower than the thermoreversible reversal temperature range, that is, at a temperature not lower than the temperature range (A) and the temperature (C). be able to. Constant temperature heating unit 103, capstan 1
Conveyance sections such as capstans 106, 107, and 108 are provided on the conveyance lines of the respective sections such as the cooling section and the thermal printing section 104 also serving as 09.

Next, a method for recording a thermoreversible recording medium using the recording apparatus for a thermoreversible recording medium will be described.

A thermoreversible recording medium 101 such as a card or a sheet is inserted into a receiving section 102 and transported to a constant temperature heating section 103. The thermoreversible recording medium 101 in the constant temperature heating unit 103
The thermoreversible reversal temperature range (A), for example, 60 to 70 ° C.
For 20 to 100 milliseconds. In this heating, as shown in FIG. 1, a thermoreversible reaction can be caused by transporting on a heating plate heated to 60 to 70 ° C. by a capstan 106. Next, Capstan 1
09 by means of a cooling unit also serving as a thermoreversible recording medium 101
Is cooled to a thermoreversible reversal temperature range or lower, for example, 50 ° C. or lower, to bring the thermoreversible recording medium 101 into an opaque state (B). In addition, the capstans 106 and 107 serving as transport units,
108 or the cooling roller is conveyed at a speed corresponding to the thermal printing speed, 5 to 50 cm / second.

Next, the thermal printing unit 104 heats the material to a temperature not lower than the temperature range (A), that is, a temperature not lower than the thermoreversible reversal temperature range (temperature (C)), for example, 90 ° C. or higher. By selectively heating to a shape, the heated portion is selectively made transparent. Capsta
When the thermoreversible recording medium is conveyed and returned to room temperature, the thermoreversible recording medium selectively becomes a transparent state (D). That is, the printed portion becomes transparent, and the unrecorded portion is obtained from the take-out unit 105 while being opaque.

When the thermoreversible recording medium 101 thus obtained is viewed on, for example, black paper, a recording paper having a transparent portion and an opaque portion having a contrast of 5 or more can be obtained. In the case of a thermoreversible recording medium having a configuration that can be used as it is as a thermoreversible recording medium or as a reflection medium, it is not necessary to view on a black paper in this way.

In the present embodiment, an example is shown in which printing is performed by using a thermoreversible recording medium 101 using a thermoreversible material which becomes transparent when heated above the thermoreversible reversal temperature range. However, it is also possible to realize print recording in a mode opposite to that of the present embodiment. In other words, when the material is heated to a temperature higher than the thermoreversible reversal temperature range, the material may not be in a transparent state but return to an opaque state when returned to room temperature. In the case of this material, it becomes transparent by heating to the thermoreversible inversion temperature range. Naturally, the present embodiment can be similarly applied to a thermoreversible recording medium having such characteristics.

According to the thermoreversible recording medium recording apparatus of the present embodiment, even if the thermoreversible recording medium 101 is once heated to a temperature higher than the thermoreversible inversion temperature range and recorded by printing, it is again set to the thermoreversible inversion temperature range. By heating, it can be reproduced by erasing all previously recorded prints. Further, by heating the reversible thermoreversible recording medium 101 to a temperature higher than the thermoreversible reversal temperature range again to print and record,
A new print record is obtained.

[0037]

Embodiment 2 FIG. 2 shows a thermoreversible recording medium recording apparatus according to another embodiment of the present invention.

Reference numeral 202 denotes a receiving / discharging section having an opening for receiving and discharging the thermoreversible recording medium 201 such as a card or a sheet into the thermoreversible recording medium recording apparatus. A plurality of capstans 204, 208, 20 are provided on the transport line of the thermoreversible recording medium 201 in the thermoreversible recording medium recording device.
5, 207 and 206 are arranged to form a transport section. On the capstan 208, the thermoreversible recording medium 20
1 has a thermal printing unit 211 heated to a temperature higher than the thermoreversible reversal temperature range for thermal printing.
7, a constant temperature heating unit 209 heated to a thermoreversible reversal temperature range for erasing and reproducing all prints recorded on the thermoreversible recording medium 201 is provided.

The capstan 206 also serves as a cooling roller and constitutes a cooling unit. The function of the cooling unit is to cool the thermoreversible recording medium 201 heated by the constant temperature heating unit 209 to make the thermoreversible recording medium 201 opaque. Further, an optical sensor 203 for detecting the passage of the thermoreversible recording medium 201 is disposed in the receiving / discharging section 202, and a cooling section also serving as the capstan 206 detects the passage of the cooling section of the thermoreversible recording medium 201. The optical sensor 210 is arranged. The capstan 206 has a reversing mechanism for reversing the rotation direction.

Further, in the thermoreversible recording medium recording apparatus, a receiving / discharging section 202, a thermal printing section 211, a constant temperature heating section 209, a cooling section, and a reversing mechanism are arranged in this order. In FIG. 2, the capstan 206 of the cooling unit has a reversing mechanism, and the cooling unit and the reversing mechanism may be arranged in the same part. Further, the thermal printing unit 211 has a mechanism for approaching or leaving the transport unit, and the constant temperature heating unit 209 has a mechanism for approaching or leaving the capstan 207 .

Next, a recording method of the thermoreversible recording medium 201 using the thermoreversible recording medium recording apparatus will be described with reference to the flowchart shown in FIG. 6 and the aforementioned thermoreversible recording medium recording apparatus of FIG. I do.

A thermoreversible recording medium 201 such as a card or a sheet is inserted into a receiving / ejecting section 202. When the thermoreversible recording medium 201 passes through the receiving / discharging section 202, the optical sensor 203 detects the passage, and the capstans 204, 205, 206, 207, and 208 serving as a conveying system rotate, and the thermoreversible recording medium is rotated. The conveyance of 201 is started. The thermoreversible recording medium 201 includes capstans 204, 208, 20
5 and the thermoreversible inversion temperature range in the constant temperature heating unit 209,
For example, heating is performed at 60 to 70 ° C. for 20 to 100 milliseconds.

As shown in FIG. 2, the constant-temperature heating unit 209 controls the conveyance speed under the heating plate heated to the thermoreversible reversal temperature range (A) 60 to 70 ° C. by the capstan 207 to 5 to 5 mm.
It is transported at 0 cm / sec to cause a thermoreversible reaction. The constant temperature heating unit 209 is controlled at a constant temperature.
Similar effects can be obtained by using a heating roller or the like. The reaction in the thermoreversible reversal temperature range is slower by about two orders of magnitude than the reaction in the thermoreversible reversal temperature range or higher (C). Therefore, the constant temperature heating unit 209 such as a heating plate or a heating roller is used for the thermoreversible recording medium. The size is determined according to the heating time of 201.

Next, the thermoreversible recording medium 201 heated to the thermoreversible reversal temperature range (A) as described above is transferred to the thermoreversible reversal temperature range below the thermoreversible reversal temperature range, for example, 50, before being conveyed to the next thermal printing section. The temperature of the thermoreversible recording medium 201 is changed to an opaque state (B) by cooling to below ℃. For this cooling, the heat is applied to the thermoreversible recording medium 2 by cooling the cap to a temperature below the thermoreversible reversal temperature range, for example, below 50 ° C.
01 is set to an opaque state (B). If the capstan 206 alone is insufficient for cooling, a cooling roller is separately provided.

Next, the thermoreversible recording medium 201 is cooled.
The optical sensor 210 detects passage through the capstan 206 also serving as a unit, and at the same time, the rotation direction of the capstans 204, 205, 206, 207, and 208 of the transport system is reversed. The transport speed of each inverted capstan is fast in accordance with the thermal printing speed in the thermal printing unit 211, for example, 5
0 to 200 cm / sec. When the capstans 204, 205, 206, 207, and 208 of the transport system rotate in the reverse direction, the constant-temperature heating unit 209 formed of a heating plate is simultaneously rotated in FIG.
Is moved away from the capstan 207 by moving in the dotted line direction shown in FIG.

Next, the thermal printing unit 211 is moved in the direction of the dotted line in FIG.
08. The thermal printing unit 211 heats the thermoreversible reversal temperature range or higher (C), for example, 90 ° C. or higher, and in this embodiment, heats the thermal printing unit 211 using a thermal head to selectively make it transparent. .

In the thermal printing unit 211, the thermoreversible recording medium 201 is conveyed by the capstan 208 of the conveying system, further conveyed by the capstan 204, and returned to a temperature lower than the thermoreversible reversal temperature range. The medium 201 is selectively brought into a transparent state (D). That is, the printed portion becomes transparent, and the non-printed portion remains opaque. The thermoreversible recording medium 201 printed and recorded in this manner is discharged from the receiving / discharging section 202 inserted first.

When the thermoreversible recording medium 201 disappears from the receiving / discharging section 202, the optical sensor 203 detects that, and the capstans 204, 20 constituting the transport system.
5, 206, 207, and 208 are stopped, the thermal printing unit 211 made of a thermal head is separated from the capstan 208, and the constant temperature heating unit 209 made of a heating plate is
07. This state is the thermoreversible recording medium 2
01 is waiting.

By viewing the thus obtained thermoreversible recording medium 201 on, for example, black paper, a recording paper having a transparent portion and an opaque portion having a contrast of 5 or more can be obtained.

As the thermoreversible recording medium 201, FIG.
The structure shown in (b), that is, a thermoreversible recording medium 20 composed of a light absorbing layer or a light reflecting layer 63 on a base 60, a thermoreversible recording layer 61 thereon, and a protective film 62 thereon.
No. 1 does not need to be viewed on black paper because the contrast between the transparent portion and the opaque portion is 5 or more even as it is.

In the above-described embodiment, the capstans 204, 205, 206, 207, and 208 serving as the transport units are provided.
Varies depending on the thermal response characteristics of the thermoreversible recording medium 201 to be used, and is adjusted to an appropriate value. Since the thermal response characteristics generally differ between erasing and recording, the transport speed of the thermoreversible card must be changed depending on the transport direction.

Further, depending on the type of thermoreversible material used for the thermoreversible recording medium 201, a mode in which the thermoreversible property is opposite to that of the present embodiment can be realized. That is, by heating above the thermoreversible reversal temperature range, there is a case in which when the temperature is returned to room temperature, the material does not become transparent but becomes opaque. In this case, by heating to a thermoreversible reversal temperature range, a transparent state is obtained. Naturally, the same method can be applied to a device having such characteristics.

Further, as described in the present embodiment, the size of the heating plate is optimized by performing the constant temperature heating by the heating plate, that is, by increasing the length of the heating plate,
It can be transported at a high speed according to the speed of thermal printing.

The thermoreversible recording medium recording apparatus of the present embodiment
Compared to Example 1, the thermoreversible recording medium 201 mouth same which is discharged mouth for insertion receiving discharge portion 202
In addition, the advancing direction of the thermoreversible recording medium 201 is reversed in the middle, and a constant temperature heating unit 209 for heating and cooling to the thermoreversible reversal temperature range on the outward path to erase the print record is provided so as to act. Since the thermal printing section 211 for selectively heating and printing in a pattern over the thermoreversible reversal temperature range is provided, a small and easy-to-use thermoreversible recording medium recording apparatus can be obtained.

[0055]

Embodiment 3 FIG. 3 shows a recording apparatus for a thermoreversible recording medium according to still another embodiment of the present invention.

Reference numeral 302 denotes a receiving / discharging unit having an opening for receiving and discharging a thermoreversible recording medium 301 such as a card or a sheet into a thermoreversible recording medium recording apparatus. A plurality of capstans 304, 305, 30 are provided on the transport line of the thermoreversible recording medium 301 in the thermoreversible recording medium recording apparatus.
6 are arranged to form a transport section. Capstan 3
A heating unit 307 made of a thermal head is arranged on 06. The heating unit 307, the thermoreversible recording medium 301 is heated to thermally reversible inversion temperature range (A), the printing recorded in the thermoreversible recording medium 301 to erase all the constant temperature heating for playing And printing heating for printing by heating to a temperature not lower than the thermoreversible reversal temperature range (C).

The capstan 305 also serves as a cooling roller and forms a cooling unit. The function of the cooling unit is to cool the thermoreversible recording medium 301 heated by the heating unit 307 and make the thermoreversible recording medium 301 opaque. Further, the thermoreversible recording medium 30
An optical sensor 303 for detecting the passage of No. 1 is arranged.
An optical sensor 308 for detecting the passage of the thermoreversible recording medium 301 through the cooling unit is provided in the capstan 305 also serving as a cooling unit. The capstan 305 has a reversing mechanism for reversing the rotation direction.

Further, in the thermoreversible recording medium recording apparatus, a receiving / discharging section 302, a heating section 307, a capstan 305 also serving as a cooling section, and a reversing mechanism are arranged in this order. In FIG. 3, the capstan 305 has a reversing mechanism, and the cooling unit and the reversing mechanism may be arranged in the same part.

Next, a recording method of the thermoreversible recording medium 301 using the thermoreversible recording medium recording apparatus will be described with reference to the flowchart shown in FIG. 7 and the aforementioned thermoreversible recording medium recording apparatus of FIG. I do.

The thermoreversible recording medium 301 such as a card or a sheet is inserted into the receiving / ejecting section 302. When the thermoreversible recording medium 301 passes through the receiving / discharging section 302, the optical sensor 303 detects the passage, and the capstans 304, 305, and 306, which are transport systems, rotate to transport the thermoreversible recording medium 301. Start. The thermoreversible recording medium 301 is sent to the capstan 304 and heated by the heating unit 307 at a thermoreversible reversal temperature range, for example, 60 to 70 ° C. for 20 to 100 milliseconds.

As shown in FIG. 3, the heating section 307 conveys under the heating plate heated to the thermoreversible reversal temperature range (A) 60 to 70 ° C. by the capstan 306 at a conveying speed of 5 to 50 cm / sec. To cause a thermoreversible reaction. Since the reaction in the thermoreversible reversal temperature range is slower by about two orders of magnitude than the reaction in the thermoreversible reversal temperature range or higher (C),
The conveying speed by the capstan is adjusted to, for example, the above speed.

Next, the thermoreversible recording medium 301 heated to the thermoreversible reversal temperature range (A) as described above is cooled to a temperature lower than the thermoreversible reversal temperature range, for example, 50 ° C. or lower. The medium is made opaque (B). In this cooling, the thermoreversible recording medium 301 is cooled to an opaque state (B) by cooling to a temperature lower than the thermoreversible reversal temperature range, for example, 50 ° C. or lower, by the capstan 305 also serving as a cooling roller. If cooling is insufficient with only the capstan 305, a cooling roller is separately provided.

Next, the thermoreversible recording medium 301 is cooled.
The optical sensor 308 detects the passage through the capstan 305 also serving as a unit, and at the same time, the rotation direction of the capstans 304, 305, 306 of the transport system is reversed. Simultaneously with the reversal, the temperature of the heating unit 307 is switched from the temperature for heating and printing, that is, from the thermoreversible inversion temperature range to the thermoreversible inversion temperature range or more. The transport speed of each inverted capstan is high according to the thermal printing speed in the heating unit 307, for example, 50 to 200 cm / sec.

Next, the thermoreversible recording medium 301 is conveyed, brought into contact with a heating section 307 composed of a thermal head, and is selectively heated to a thermoreversible reversal temperature range (C), for example, 90 ° C. or higher. , Selectively transparent. In the heating section 307, the thermoreversible recording medium 301 is conveyed by the capstan 306 of the conveying system, further conveyed by the capstan 304, and returned to a temperature lower than the thermoreversible reversal temperature range. Selectively becomes a transparent state (D). That is, the printed portion becomes transparent, and the non-printed portion remains opaque. The thermoreversible recording medium 301 printed and recorded in this way is discharged from the receiving / discharging section 302 inserted first.

When the thermoreversible recording medium 301 disappears from the receiving / discharging section 302, the optical sensor 303 detects that, and the capstans 304, 30 constituting the transport system are detected.
5, 306 is stopped, and the temperature of the heating unit 307 is changed from the thermoreversible reversal temperature range to the thermoreversible reversal temperature range. This state is a state of waiting for the thermoreversible card.

The thermoreversible recording medium 30 obtained by the above method
For example, by viewing 1 on a black paper, a recording paper having a transparent portion and an opaque portion having a contrast of 5 or more can be obtained.

In the above-described embodiment, the capstans 304, 305, and 306 serving as the transport units differ depending on the thermal response characteristics of the thermoreversible recording medium 301 used, and are adjusted to appropriate values. Since the thermal response characteristics are generally different between erasing and recording, the thermoreversible recording medium 30
The transport speed of 1 needs to be changed depending on the transport direction.

Further, depending on the type of the thermoreversible material used for the thermoreversible recording medium 301, a mode in which the thermoreversible property is opposite to that of this embodiment can be realized. That is, by heating above the thermoreversible reversal temperature range, there is a case in which when the temperature is returned to room temperature, the material does not become transparent but becomes opaque. In this case, by heating to a thermoreversible reversal temperature range, a transparent state is obtained. Naturally, the same method can be applied to a device having such characteristics.

The recording apparatus for the thermoreversible recording medium of the present embodiment
An apparatus into which the thermoreversible recording medium 301 is inserted and a port through which the thermoreversible recording medium 301 is ejected have the same receiving / ejecting section 302, and the thermoreversible recording medium 301 is heated to a thermoreversible reversal temperature range and reproduced. The same heating unit 3 as the apparatus for performing heating printing on the thermoreversible recording medium 301 using a thermal head.
07, it was possible to obtain a compact and easy-to-use thermoreversible recording medium recording apparatus.

The present invention is not limited to the above-described embodiment, and various modifications can be made based on the gist of the present invention.

[0071]

The thermoreversible recording medium recording apparatus and recording method of the present invention have both a constant-temperature heating section and a thermal printing section, so that the thermoreversible recording medium is erased before printing and recording. After complete reproduction, it can always be recorded. Therefore, by printing and recording on a thermoreversible recording medium such as a card or a sheet using the thermoreversible recording medium recording apparatus of the present invention, the thermoreversible recording medium can be reproduced and used any number of times.

Further, in the thermoreversible recording medium recording apparatus of the present invention, the port into which the thermoreversible recording medium is inserted and the port through which the thermoreversible recording medium is discharged are formed in the same receiving / discharging section, and the direction in which the thermoreversible recording medium travels. Is reversed in the middle, and is heated to the thermoreversible reversal temperature range on the outward path, and is provided so as to act as a constant-temperature heating section for cooling and erasing the print record. The provision of the thermal printing unit for printing and recording by heating provided a compact and easy-to-use thermoreversible recording medium recording apparatus.

Further, the thermoreversible recording medium recording apparatus of the present invention comprises a device for reproducing a thermoreversible recording medium by heating it to a thermoreversible reversal temperature range, and a thermal head or the like for reproducing the reproduced thermoreversible recording medium. Since the apparatus for performing printing and heating was performed in the same heating section, a small and easy-to-use thermoreversible recording medium recording apparatus could be obtained.

[Brief description of the drawings]

FIG. 1 shows an embodiment of a thermoreversible recording medium recording apparatus of the present invention.

FIG. 2 shows a thermoreversible recording medium recording apparatus according to another embodiment of the present invention.

FIG. 3 shows a recording apparatus for a thermoreversible recording medium according to still another embodiment of the present invention.

FIG. 4 shows a layer configuration of a thermoreversible recording medium used in the present invention.

FIG. 5 shows a hysteresis curve of temperature-light transmittance of the thermoreversible recording medium used in the present invention.

FIG. 6 is a flowchart showing the operation of the thermoreversible recording medium recording device of the present invention.

FIG. 7 is a flowchart showing the operation of another thermoreversible recording medium recording device of the present invention.

[Explanation of symbols]

101, 201, 301 Thermoreversible recording medium 102 Receiving unit 202, 302 Receiving / discharging unit 103, 209 Constant temperature heating unit 104, 211 Thermal printing unit 105 Removal unit 106, 107, 108, 109, 204, 205, 2
06, 207, 208, 304, 305, 306
Capstan 203, 210, 303, 308 Optical sensor 307 Heating unit 50, 60 Base 51, 61 Thermoreversible recording layer 52, 62 Protective film 63 Light absorbing layer or light reflecting layer

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) B41J 29/36 B41M 5/26 B41M 5/36 B42D 15/10 551

Claims (13)

(57) [Claims] 1. A receiving and discharging unit for receiving and discharging a thermoreversible recording medium, (2) a constant temperature heating unit for heating to a thermoreversible inversion temperature range, and (3) a thermoreversible inversion temperature range. A cooling unit for cooling the heated thermoreversible recording medium to room temperature; (4) a thermal printing unit for printing by heating the cooled thermoreversible recording medium to a temperature higher than the thermoreversible inversion temperature; A transport section for transporting the thermoreversible recording medium to a discharge section, a constant temperature heating section, a cooling section, and a thermal printing section; and (6) being disposed in the receiving and discharging section to detect passage of the thermoreversible recording medium. (7) a reverse rotation command sensor for detecting passage of a thermoreversible recording medium disposed in the cooling unit; and (8) a thermal printing unit is moved upward by a signal from the reception and discharge sensor, and the reverse rotation is performed. Lowering the thermal printing section by the signal from the command sensor An elevating mechanism, (9) an elevating mechanism that lowers the constant temperature heating unit according to a signal from the receiving / discharging sensor and raises the constant temperature heating unit according to a signal from the reverse rotation instruction sensor, and (10) a signal from the reverse rotation instruction sensor. A thermoreversible recording medium recording device, comprising: a reversing mechanism for reversing the advance of the transport unit by means of a reversing mechanism. 2. A receiving and discharging unit, a thermal printing unit, a constant temperature heating unit,
The cooling unit, and the reversing mechanism are arranged in this order, the thermal printing unit has a mechanism that approaches and separates the transport unit, and the constant temperature heating unit includes a mechanism that approaches and separates the transport unit. The recording apparatus for a thermoreversible recording medium according to claim 1, comprising: Wherein the cooling unit and reversing mechanism is characterized by being composed of integral parts according to claim 1 or 2
The recording device for a thermoreversible recording medium according to the above. 4. A receiving / discharging section for receiving and discharging a thermoreversible recording medium, and (2) a function of heating to a thermoreversible inversion temperature range and a thermoreversible recording medium at a temperature higher than the thermoreversible inversion temperature. A heating section having a function of heating and printing; (3) a cooling section for cooling a thermoreversible recording medium heated to a thermoreversible reversal temperature range to room temperature; and (4) progression of the thermoreversible recording medium. A reversing mechanism for reversing the direction; (5) a transport unit for transporting the thermoreversible recording medium to each of the units; and (6) a receiving unit disposed in the receiving and discharging unit for detecting the passage of the thermoreversible recording medium. A discharge sensor; (7) a reverse rotation command sensor for detecting passage of a thermoreversible recording medium disposed in the cooling unit; and (8) a heating unit is switched to a thermoreversible reversal temperature by a signal from the receiving and discharging sensor. In addition, the reverse rotation command sensor Thermoreversible recording medium recording apparatus characterized by comprising a switching means for switching over the thermally reversible inversion temperature heating section through No.. Wherein said cooling unit and reversing mechanism thermoreversible recording medium recording apparatus according to claim 4, characterized in that it consists integral part. 6. A thermoreversible recording medium is inserted into a receiving / discharging section, (2) a transport section starts operating, and (3) a thermoreversible recording medium is transported by a constant temperature heating section while being transported. (4) Heating the reversible recording medium while transporting the thermoreversible recording medium, and cooling it to a temperature lower than the thermoreversible reversing temperature range in the cooling section to erase the print record. (5) Propagation direction of the thermoreversible recording medium And (6) heating the thermoreversible recording medium to a temperature higher than the thermoreversible reversal temperature range in the thermal printing section while transporting the thermoreversible recording medium, and (7) discharging the thermoreversible recording medium from the receiving and discharging section. A recording method for a thermoreversible recording medium, comprising: 7. A start of the operation of the transport unit, thermoreversible recording medium is a thermoreversible recording medium according to claim 6, characterized in that by detecting by a sensor that is inserted into the receiving discharge portion Recording method. 8. The reversal of the traveling direction of the thermoreversible recording medium is as follows:
7. The recording method for a thermoreversible recording medium according to claim 6, wherein the passage of the thermoreversible recording medium through the cooling section is detected by a sensor. 9. The heating in the constant-temperature heating section and the heating in the thermal printing section are performed such that when the thermoreversible recording medium advances on the outward path, the thermal printing section is located at a position distant from the transport path of the thermoreversible recording medium. Move,
In addition, the constant temperature heating unit moves to a position close to the transport path of the thermoreversible recording medium and heats the thermoreversible recording medium. Go to the transport path and away from the position of the media, and claim 6, wherein the thermal printing unit is characterized in that by moving the position close to the transport path of the thermoreversible recording medium to heat the thermoreversible recording medium Recording method for a thermoreversible recording medium. 10. A thermoreversible recording medium is inserted into a receiving / ejecting section, (2) an operation of a transport section is started, and (3) a thermoreversible inversion is performed in a heating section while transporting the thermoreversible recording medium. (4) Heating the thermoreversible recording medium while transporting the thermoreversible recording medium to cool the thermoreversible reversal temperature range below the reversible temperature range in the cooling section, thereby erasing the print record. (6) heating the thermoreversible recording medium to a temperature above the thermoreversible reversal temperature range in the same heating section while transporting the thermoreversible recording medium, and performing thermal printing; (7) receiving the thermoreversible recording medium in the same manner as described above A recording method for a thermoreversible recording medium, wherein the recording medium is discharged from a discharge section. 11. The thermoreversible recording medium according to claim 10 , wherein the operation of the transport unit is started by detecting that the thermoreversible recording medium has been inserted into the receiving / discharging unit by a sensor. Recording method. 12. The thermoreversible recording medium according to claim 10 , wherein the reversal of the traveling direction of the thermoreversible recording medium is performed by detecting the passage of the thermoreversible recording medium through a cooling section with a sensor. Recording method. 13. The heating in the constant-temperature heating section and the heating in the thermal printing section are performed when the thermoreversible recording medium travels on the outward path, and the thermal printing section is located at a position distant from the transport path of the thermoreversible recording medium. When the thermoreversible recording medium moves and moves to a position close to the transport path of the thermoreversible recording medium and heats the thermoreversible recording medium, when the thermoreversible recording medium advances on the return path, the thermostatic heating section heats up. The thermoreversible recording medium is heated by moving to a position distant from the transport path of the reversible recording medium and moving the thermal printing unit to a position close to the transport path of the thermoreversible recording medium. Item 1
0. A recording method for a thermoreversible recording medium according to item 0 .