Information
-
Patent Grant
-
6713430
-
Patent Number
6,713,430
-
Date Filed
Monday, April 9, 200123 years ago
-
Date Issued
Tuesday, March 30, 200420 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Wood, Phillips, Katz, Clark & Mortimer
-
CPC
-
US Classifications
Field of Search
US
- 503 201
- 503 226
- 503 204
-
International Classifications
-
Abstract
A leaf of printed matter has a metachromatic image 2 printed with an ink thermally changing its color and a non-metachromatic image 3 of a colorant not changing its color. A principal figure 5 is formed of the colorant, and a background 6 is formed with the metachromatic ink. The printed matter 1 may be used to transfer its images to a cup 10. The ink of the background scene 6 in the outer layer will turn to colorless within a prescribed range of temperatures, rendering visible only the central principal figure 5. At lower temperatures, the metachromatic ink will restore its color to cause the background for instance a snowy scene to appear, thus affording a novel and fantastic visual effect.
Description
FIELD OF THE INVENTION
The present invention relates to reversibly metachromatic printed matter prone to change in color in response to temperature change. The printed matter of the invention will be used preferably as transfer paper sheets or as decorative seals.
BACKGROUND OF THE INVENTION
There are known in the art some kinds of printed matter prepared using (a) metachromatic ink(s) such that characters and/or figures will appear on them at prescribed temperatures (see for example the Japanese Utility Model Publications No. Hei.4-6938 and No. Hei.4-6939).
Each of such printed matter comprises an underlayer of a non-metachromatic ink (viz., an ordinary ink) applied to a substrate so as to provide any desired characters and/or figures. An upper layer covering the non-metachromatic under-layer is composed of a thermally metachromatic ink so that any superimposed image will lose or restore its color in response to change in temperature. The whole surface area of such a non-metachromatic printed image is completely covered with the metachromatic image in the prior art printed matter.
At room temperature or moderate temperatures, the colored meta-chromatic print hides the non-metachromatic print, whereby such a prior art printed matter sheet will be observed as if it were an entirely monochromatic sheet. However at predetermined temperatures, the metachromatic printed image in the upper layer of the printed matter will become colorless, thus rendering visible the underlying non-metachromatic printed image such as characters.
SUMMARY OF THE INVENTION
As discussed above, those prior art printed matter sheets have been printed with such a thermally metachromatic ink covering the entirety of non-metachromatic printed image. Therefore, characters and the like have been allowed to appear in a normal solid-color surface, in a simple manner failing to afford any peculiar or ornamental effect.
An object of the present invention is to provide a novel type of printed matter that can produce a more fantastic visual effect in use.
Each surface of the printed matter of the invention is composed of a first image printed with at least one of first thermo-metachromatic colorants prone to reversible change in color due to change in ambient temperature, and a second image printed either with a non-metachromatic colorant or with at least one of second thermo-metachromatic colorants prone to change in color at temperatures different from those at which the first colorants will change their color. The first and second images proposed herein may be printed on respective discrete regions in the printed matter surface.
In this invention, the concept of ‘reversible change in color in response to ambient temperature’ as summarized above does include color change between chromatic colors such as red and yellow, color change between a chromatic color and an achromatic color for example between red and white, and color change between any chromatic or achromatic color and transparency for example between red and transparency.
The term ‘printed images’ used herein include characters, letters, figures and the like.
As mentioned above, the thermally metachromatic image and the thermally non-metachromatic image may be printed on the discrete regions in the printed matter of the invention. This means that the latter image will be sensed irrespective of any change in temperature so as to provide a basic pattern to which the former metachromatic image is added at prescribed temperatures.
In another mode of carrying out the present invention, either the first or second printed image may occupy an almost entire region of the printed matter surface, and correspondingly either the second or first image occupies at least one portion of the remainder region so as to serve as a background image or scene.
Thus, either of the printed images is disposed fully over the entire surface, to be accompanied by the background that is formed with the other printed image capable of producing various scenes such as a summer scene, a winter scene or any other designed scene.
In still another mode, the first and second printed images may be line drawings that are of the same configuration at least in part and overlap one another at least in part.
Such a composite image consisting of the line drawings overlapping one another at least partially will not greatly change its pattern but will merely change its color.
In a further mode, the first printed image may be superimposed on the second non-metachromatic image so as to expose a part thereof.
This type of the printed matter comprises the metachromatic image formed with a metachromatic colorant reversibly changeable between its colorless state and its colored state.
In contrast with the prior art overlying thermo-metachromatic image completely covering the underlayer, the overlying metachromatic layer in this invention does hide only in part the non-thermo-metachromatic underlayer image. Therefore, a curious impulse will come over any viewer of this printed matter, wondering what is a hidden part of that image underlying the surface layer.
In a still further mode, the first printed image may be superimposed on the second printed image of a meaning relevant to the first one.
Such a non-metachromatic and metachromatic images in the printed matter of the invention are of supplementary meanings to give viewers an intellectual impression or a feeling of curiosity.
The first image may be formed of any thermo-metachromatic colorant that reversibly changes in color depending on ambient temperature, from its colorless state to its colored state or vice versa.
If the second image is formed of at least one of second thermo-metachromatic colorants prone to change in color at temperatures different from those at which the first colorants will change their color, the second thermo-metachromatic colorant may be one that reversibly changes in color depending on ambient temperature, from its colorless state to its colored state or vice versa.
The printed matter summarized above may be used as transfer sheets or as seals, and the first printed image may be a polychromatic image of two or more colors.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a perspective scheme of printed matter provided in a first embodiment of the present invention;
FIG.
2
(
a
) is a front elevation of an example of the printed matter that is prepared in the first embodiment but has not undergone yet any change in temperature;
FIG.
2
(
b
) is a front elevation of the printed matter example prepared in the first embodiment but has undergone change in temperature;
FIG.
3
(
a
) is a front elevation of a further example of the printed matter that is prepared in the first embodiment but has not undergone yet any change in temperature;
FIG.
3
(
b
) is a front elevation of the further printed matter example prepared in the first embodiment but has undergone change in temperature;
FIG. 4
is a perspective view of a cup on which the printed matter of the first embodiment has been stuck;
FIG. 5
is a perspective scheme of printed matter provided in a second embodiment of the present invention;
FIG.
6
(
a
) is a front elevation of an example of the printed matter that is prepared in the second embodiment but has not undergone yet any change in temperature;
FIG.
6
(
b
) is a front elevation of the printed matter example prepared in the second embodiment but has undergone change in temperature;
FIG. 7
is a perspective scheme of printed matter provided in a third embodiment of the present invention;
FIG.
8
(
a
) is a front elevation of an example of the printed matter that is prepared in the third embodiment but has not undergone yet any change in temperature;
FIG.
8
(
b
) is a front elevation of the printed matter example prepared in the third embodiment but has undergone change in temperature;
FIG. 9
is a perspective scheme of printed matter provided in a fourth embodiment of the present invention;
FIG.
10
(
a
) is a front elevation of an example of the printed matter that is prepared in the fourth embodiment but has not undergone yet any change in temperature;
FIG.
10
(
b
) is a front elevation of the printed matter example prepared in the fourth embodiment but has undergone change in temperature;
FIG. 11
is a perspective scheme of printed matter provided in a fifth embodiment of the present invention;
FIG. 12
is a perspective view of the printed matter elements prepared in the fifth embodiment and overlaid one on another;
FIG.
13
(
a
) is a front elevation of an example of the printed matter that is prepared in the fifth embodiment but has not undergone yet any change in temperature; and
FIG.
13
(
b
) is a front elevation of the printed matter example prepared in the fifth embodiment but has undergone change in temperature.
THE PREFERRED EMBODIMENTS OF THE INVENTION
<First Embodiment>
Now, the first embodiment will be described referring to
FIGS. 1
to
4
.
At first, the elementary construction of the first embodiment will be described referring to
FIGS. 1 and 4
. Each leaf of printed matter
1
in this embodiment has a printed image
2
formed of a thermo-metachromatic ink (as a metachromatic colorant) and a further printed image
3
formed of a non-metachromatic colorant. A principal
figure 5
is printed with the non-metachromatic colorant, with a background scene
6
being printed with the thermo-metachromatic ink.
In other words, the principal
figure 5
in the printed leaf is composed of the non-metachromatic ink and all the remainder regions other than this
figure 5
are composed of the thermo-metachromatic ink.
The printed matter
1
may for example be a transfer sheet whose prints will be transferred in use for instance to an article such as a cup
10
or the like shown in FIG.
4
. The transferred images on the cup
10
are reversed inside out.
The printed matter
1
comprises a plastics film
11
as a substrate, and the thermo-metachromatic image
2
as a first layer is printed on this substrate. Subsequently, the non-thermo-metachromatic image
3
as a second layer is printed on the first layer.
The terms ‘first layer’ and ‘second layer’ are used here only for brief and simple description. The first thermo-metachromatic colorant layer has no portion overlapping the second non-metachromatic colorant layer, but both the layers are arranged side by side on a common plane.
The metachromatic image
2
of the first layer is a print of a thermo-metachromatic ink that will reversibly change its state from ‘colorless’ to ‘colored’ or vice versa above or below a prescribed temperature. An example of such a metachromatic ink is a colorant whose main ingredient is a combination of a compound serving as an electron donor and a mating compound serving as an electron acceptor. The donor is a coloring agent and the acceptor is a developing agent acting thereon. A printing ink included in this type of the thermo-metachromatic colorants is disclosed in the Japanese Patent Publication No. 52-7764. Similar thermo-meta-chromatic colorants will be found in ibid. No. 51-35216, ibid. 51-35414 and ibid. 51-44708.
Those inks may have any desired hue such as red, blue, yellow, green, orange, violet or any sophisticated color between them, based on blend ratio of the inks. It is convenient to the invention that they will reversibly lose or restore their hue within a considerable wide range of temperatures.
Such a thermo-metachromatic colorant may be prepared in the form of a printing ink that will then applied to the whole surface of plastics film
11
or spotted thereto to form the metachromatic layer.
In the embodiment of
FIG. 1
, the first layer of the metachromatic print
2
presents a snowing scene as the background
6
, all over the surface except for the principal figure
5
.
The non-metachromatic print
3
as the second layer is formed of any of ordinary types of printing inks for wide uses, by the conventional printing method.
A generally central region
12
devoid of the metachromatic printed image
2
is, in the embodiment of
FIG. 1
, printed with the ordinary printing ink to give the principal figure
5
.
The printed matter
1
in this embodiment has the non-metacromatic image consisting only of the main figure
5
.
As noted above, this printed matter
1
will be used to transfer its printed images onto the cup.
After transfer of the images, the surface metachromatic ink forming the background
6
will become or remain colorless within a prescribed range of temperatures, making only the central
figure 5
visible to observers of the cup. If however ambient atmosphere becomes colder than a lower temperature limit, then the metachromatic ink will become colored to thereby allow the snowing background
6
to appear.
FIGS.
2
(
a
) and
2
(
b
) show a virtual example 15 of the embodiment, wherein the known deformation portrait drawn by the Japanese painter ‘Sharaku’ is printed to a lower right-hand region with use of a non-metachromatic regular ink. The background composed of a Japanese castle, the Mount Fuji, a Japanese classic dancer girl ‘Maiko’ and cherry blossoms is printed with a thermo-metachromatic ink.
In the printed matter shown in FIGS.
2
(
a
) and
2
(
b
), both the deformation portrait as the second layer and the background scene including the castle and so on as the first layer are multicolored. The portrait is a full-color print formed of the non-metachromatic ink containing four colorants whose hues are blue, red, yellow and black. Likewise, the background scene is a print of the metachromatic ink also containing four colorants: blue, red, yellow and black. In detail, Mount Fuji is printed white, the sky is blue, the ‘Maiko’ has black hair, beige skin, yellow hair-ornaments, red lips and wears a Japanese classic dress ‘kimono’ colored pale-blue and bluish-yellow.
The printed matter shown in FIGS.
2
(
a
) and
2
(
b
) will stand fully-drawn in its normal state, unless its background scene surrounding ‘Sharaku’ and composed of the castle and so on does disappear in response to change in temperature into a predetermined range.
FIGS.
3
(
a
) and
3
(
b
) illustrate another virtual example 16 of the printed matter, wherein the second layer is a print of a locomotive and the first layer is a print of the Grand Canyon in the U.S.A. This composite picture will also stand fully-drawn in its normal state, unless its background scene of the Grand Canyon disappears in response to temperature shift into a predetermined range.
<Second Embodiment>
Next, the second embodiment will be described referring to
FIGS. 5
to
6
(
b
).
A metachromatic print and a non-metachromatic print in the printed matter of this embodiment shown in
FIG. 5
do overlap one another, whereas those prints in the first embodiment occupy discrete regions.
As seen in
FIG. 5
, the printed matter
20
has a first layer that is formed of a thermo-metachromatic ink giving a girl's figure as a principal image
5
and also providing the image of a tree
21
as an exemplary background scene.
A second layer of this printed matter is also composed of the principal image
5
and another image of the tree
22
that is of the same shape and disposed at the same position as that
21
in the first layer. Thus, two images of the tree are superimposed one on another though color of the tree image
22
is different from the developed color of the other tree image
21
.
Also in this embodiment, both the first and second layers of the printed matter
20
are full-color prints.
Those prints in this printed matter
20
are formed on a plastics film
11
, as in the first embodiment. The metachromatic ink for the first layer is applied first to the film
11
, and then the non-metachromatic ink for the second layer is superimposed.
Similarly, this printed matter
20
may be used to transfer its prints to a cup.
These print layers will thus be reversed inside out on the surface of the cup so that the non-metachromatic print
3
underlies the metachromatic print
2
exposed newly.
Within a prescribed range of temperatures, the images of tree
21
and girl will remain colorless in the first layer of printed matter
20
so that only the main figure
5
and the background tree
22
are visible in the second layer. However at other temperatures for instance considerably elevated temperatures, the metachromatic ink of the first layer will become colored to cause the tree image
21
in this layer to hide that
22
in the second layer. Since those tree images are of the same configuration and size but merely different in their colors, viewers would feel as if that tree had altered its color depending on ambient temperature.
A leaf of printed matter
25
shown in FIGS.
6
(
a
) and
6
(
b
) is a virtual example of the second embodiment. An automobile is printed with a non-metachromatic ink, and the scope of background such as a road is a print of a metachromatic ink. Two prints, of which one is metachromatic and the other is non-metachromatic, are thus superimposed one on another.
Therefore, at elevated temperatures, the metachromatic ink of the first layer will become colored and visible to thereby hide the road and so on in the second layer. Since those background images are of the same configuration and size but merely different in their colors, viewers would feel as if the ambient temperature had caused that road to change in color and as if the season had changed.
<Third Embodiment>
Printed matter in accordance with the third embodiment will be described referring to
FIGS. 7
to
8
(
b
).
A metachromatic print
2
in the first layer of this printed matter
30
expresses water waves that will cause viewers to imagine the summer season around a portrait, which will appear under certain conditions.
On the other hand, a non-metachromatic print
3
as the second layer contains the portrait of a girl as the main or principal
figure 5
, in addition to a landscape of snow representing the winter season. The principal figure
5
and its background printed in the second layer do cover the whole surface thereof.
The first layer in this printed matter
30
does however overlap such a background in the second layer either partly or fully.
The leaf of printed matter
30
may also be a transfer sheet having a plastics film
11
serving as the substrate thereof. Its stratum structure will be inverted when transferred to a cup
10
or the like such that its internal first layer will become the external layer in the transferred image.
Within a prescribed range of temperatures, the metachromatic ink forming the background waves will remain colorless in the printed matter
30
so that only the main figure
5
and the background landscape of snow are visible in the second layer. However at other temperatures for instance considerably elevated temperatures, the metachromatic ink will restore its color to hide that snowy landscape in the second layer.
In the printed matter
35
shown in FIGS.
8
(
a
) and
8
(
b
) as a virtual example of the third embodiment, the Mount Fuji and its surroundings are printed with the non-metachromatic ink, with a hazy landscape of them being printed with the metachromatic ink.
Both the first and second layers of this printed matter
35
are likewise full-color prints.
At elevated temperatures, the metachromatic ink will be colored to cause the hazy landscape to appear.
<Fourth Embodiment>
Now, the forth embodiment will be described with reference to
FIGS. 9
to
10
(
b
).
A leaf of printed matter
40
of this embodiment has a first layer to which the image of an automobile
41
without tires is printed.
The image of tires
42
is printed on a second layer to coincide with the automobile image
41
.
The printed matter
40
having also a plastics base film may be a transfer sheet. After transfer of those image prints to a cup
10
or the like, said layers are reversed inside out to expose the first layer.
Within a prescribed range of temperatures, the first layer will stand effective to partially hide the image of tires
42
of the second layer in the printed matter
40
so that an automobile image with tires
42
is visible. However at other temperatures for instance considerably elevated temperatures, the metachromatic colorant will lose its color to render visible only the entire image of tires
42
of the second layer.
The printed matter of this embodiment is of a feature that a certain change in temperature causes one image to be replaced with the other image wherein these images are relevant to each other. Such a quiz-like feature will inspire intellectual interest in viewers. Other examples of relevancy between images will include: relationship between a finished product and its parts, relationship between the name of a corporate and its products; relationship between some animals or plants of similar behaviors or similar species, relationship between a selected person and his or her nickname, and relationship between the person and any article for use in his or her peculiar performance.
FIGS.
10
(
a
) and
10
(
b
) show a virtual example of the fourth embodiment, wherein the external appearance and the interior of an automobile are printed with a non-chromatic ink to provide a basic image. The logotype ‘H’ as the corporate name and registered trademark of the Honda Motor Co., Ltd., a Japanese company, is also printed to completely overlap the basic image.
The logotype ‘H’ is colored blue and surrounded by a black background.
The metachromatic ink forming the first layer in this printed matter
45
will remain colored within a range of ordinary temperatures so as to hide the second layer having therein the image of the automobile. At elevated temperatures, that ink will lose color to become transparent so as to render the automobile image visible. Such replacement of one image with the other one intimately relevant thereto in the printed matter of this embodiment will give viewers a quiz-like interest.
<Fifth Embodiment>
Finally,
FIGS. 11
to
13
(
b
) show the fifth embodiment.
The printed matter
50
of this embodiment comprises a first layer printed with a thermo-metachromatic ink to give a pattern of bubbles. Small round regions representing the bubbles are devoid of ink and surrounded each with a colored background.
The figure of a flower is printed on the second layer.
The printed matter
50
having also a plastics base film
11
may be a transfer sheet. After transfer of those image prints to a cup
10
or the like, said layers are reversed inside out to expose the first layer.
The bubble-pattern print on the first layer in this printed matter
50
will remain colored within a range of ordinary temperatures so as to hide the second layer having therein the flower image. The small round regions devoid of the ink leave discrete portions of the flower to be visible from outside.
At elevated temperatures, the metachromatic ink will lose color to become transparent so as to render visible the full image of flower.
Replacement of such a normal and partial view of one image with the complete sight thereof taking place in response to change in temperature will give viewers a quiz-like interest.
A virtual example of the fifth embodiment is shown in FIGS.
13
(
a
) and
13
(
b
). Printed on the first layer are the characters ‘NISSAN’ and design as the corporate name and trademark of the Nissan Motor Co., Ltd., a Japanese company. The region representing each character of ‘NISSAN’ is devoid of ink so as to be blank. Printed on the second layer with a thermo-metachromatic ink are the image of an automobile
51
and its other trademark ‘Sunny’.
Thus, viewers can see through the void zones ‘NISSAN’ some portions of that figure, being inspired to have a feeling of curiosity. With ambient temperature raised to a certain level, the metachromatic ink turns to transparent to render visible the automobile image.
In each of the embodiments described above, the printed matter has the print image of the non-metachromatic ink. However in this invention, such a non-changeable image may be replaced with a second thermo-metachromatic ink image printed with a second metachromatic colorant. This colorant will change its normal color to a different color, so that the nature and performance of the described printed matter will not be affected to any unacceptable extent. The second metachromatic colorant may further be replaced with another one that changes its color at different temperatures from the first one, also without seriously affecting the described effect or function of the printed matter.
In summary, the printed matter of the invention is interesting in that different images appear depending on its temperature to afford a special visual or ornamental effect. The principal or certain elected figure remains visible, notwithstanding any change in the temperature, and nevertheless a further figure whose color depends on temperature will be added to the principal figure whereby a novel visual effect is produced.
In one mode of the invention, the background image alters in response to temperature change.
In another mode, temperature change does scarcely cause change in configuration of the figure and merely bring about change in its color, to thereby produce an epoch-making visual effect.
In a further mode, an upper layer printed with a metachromatic ink allows portions of a non-metachromatic image on the underlayer even if the ink stands colored. Viewers of this printed matter will thus be strongly interested to know what figure is hidden by and under the non-meta-chromatic image.
In a still further mode, a non-metachromatic print and a metachromatic print have respective meanings relevant to each other so that the printed matter will inspire an intellectual impression in the viewers' feeling.
The foregoing disclosure of specific embodiments is intended to be illustrative of the broad concepts comprehended by the invention.
Claims
- 1. Printed matter comprising:a first image printed with at least one of first thermo-metachromatic colorants prone to reversible change in color due to change in ambient temperature; and a second image printed with a colorant selected from the group consisting of non-metachromatic colorants and second thermo-metachromatic colorants prone to change in color at temperatures different from those at which the first colorants change their color, wherein one of the first and second images is printed substantially on the whole surface area of the printed matter, and one of the first and second images forms at least one portion of a background for the other image.
- 2. Printed matter as defined in claim 1, wherein the first image is exposed on an article, with the second image intervening between the first image and the article.
- 3. Printed matter as defined in claim 1, wherein the thermo-metachromatic colorants forming the first image have the property of altering a colorless state to a colored state or vice versa, depending on change in the ambient temperature.
- 4. Printed matter as defined in claim 1, wherein the printed matter is of a form selected from the group of transfer sheets and seals and articles that have images thereon transferred from the transfer sheets or seals.
- 5. Printed matter as defined in claim 1, wherein the first image is printed with at least two colors.
- 6. Printed matter comprising:a first image printed with at least one of first thermo-metachromatic colorants prone to reversible change in color due to change in ambient temperature; and a second image printed with a colorant selected from the group consisting of non-metachromatic colorants and second thermo-metachromatic colorants prone to change in color at temperatures different from those at which the first colorants change their color, wherein both the first and second images are line drawings that are of the same configuration at least partially and are superposed one on another at least in part.
- 7. Printed matter as defined in claim 6, wherein the first image is exposed on an article, with the second image intervening between the first image and the article.
- 8. Printed matter as defined in claim 6, wherein the thermo-metachromatic colorants forming the first image have the property of altering a colorless state to a colored state or vice versa, depending on change in the ambient temperature.
- 9. Printed matter as defined in claim 6, wherein the printed matter is of a form selected from the group of transfer sheets and seals and articles that have images thereon transferred from the transfer sheets or seals.
- 10. Printed matter as defined in claim 6, wherein the first image is printed with at least two colors.
- 11. Printed matter comprising:a first image printed with at least one of first thermo-metachromatic colorants prone to reversible change in color due to change in ambient temperature; and a second image printed with a colorant selected from the group consisting of non-metachromatic colorants and second thermo-metachromatic colorants prone to change in color at temperatures different from those at which the first colorants change their color, wherein the first image is superimposed on the second image, wherein the first image has at least one region devoid of the at least one of first thermo-metachromatic colorants so as to expose a part of the second image to be visible from outside.
- 12. Printed matter as defined in claim 11, wherein the first image is exposed on an article, with the second image intervening between the first image and the article.
- 13. Printed matter as defined in claim 11, wherein the thermo-metachromatic colorants forming the first image have the property of altering a colorless state to a colored state or vice versa, depending on change in the ambient temperature.
- 14. Printed matter as defined in claim 11, wherein the printed matter is of a form selected from the group of transfer sheets and seals and articles that have images thereon transferred from the transfer sheets or seals.
- 15. Printed matter as defined in claim 11, wherein the first image is printed with at least two colors.
- 16. Printed matter comprising:a first image printed with at least one of first thermo-metachromatic colorants prone to reversible change in color due to change in ambient temperature; and a second image printed with a colorant selected from the group consisting of non-metachromatic colorants and second thermo-metachromatic colorants prone to change in color at temperatures different from those at which the first colorants change their color, wherein the first image is superimposed on the second image, and the first and second images are of meanings relevant to each other.
- 17. Printed matter as defined in claim 16, wherein the first image is exposed on an article, with the second image intervening between the first image and the article.
- 18. Printed matter as defined in claim 16, wherein the thermo-metachromatic colorants forming the first image have the property of altering a colorless state to a colored state or vice versa, depending on change in the ambient temperature.
- 19. Printed matter as defined in claim 16, wherein the printed matter is of a form selected from the group of transfer sheets and seals and articles that have images thereon transferred from the transfer sheets or seals.
- 20. Printed matter as defined in claim 16, wherein the first image is printed with at least two colors.
- 21. Printed matter comprising:a first image printed with at least one of first thermo-metachromatic colorants prone to reversible change in color due to change in ambient temperature; and a second image printed with a colorant selected from the group consisting of non-metachromatic colorants and second thermo-metachromatic colorants prone to change in color at temperatures different from those at which the first colorants change their color.
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Number |
Name |
Date |
Kind |
5158924 |
Konagaya et al. |
Oct 1992 |
A |
5193854 |
Borowski et al. |
Mar 1993 |
A |
6313067 |
Maruyama |
Nov 2001 |
B1 |