FIELD OF THE INVENTION AND RELATED ART
[0001] The present invention relates to a thermal transfer recording method of transferring
multi-color images such as two-color images onto a recording medium.
[0002] The thermal or heat-sensitive transfer recording method has recently been widely
used because it has general advantages of the thermal recording method such that the
apparatus employed is light in weight, compact, free of noise, excellent in operability
and adapted to easy maintenance, and also has other advantages such that it does not
require a color- formation type converted paper but provides recorded images with
excellent durability.
[0003] The thermal recording method generally employs a thermal transfer material comprising
a heat- transferable ink containing a colorant dispersed in a heat-fusible binder
coated on a support generally in the form of sheet. The recording is generally conducted
by superposing the thermal transfer material on a recording medium such as paper so
that the heat- transferable ink layer will contact the recording medium, supplying
heat from the support side of the thermal transfer material by means of a thermal
head etc. to transfer the melted ink layer to the recording medium, thereby forming
a transferred ink image corresponding to the heat supplying pattern on the recording
medium.
[0004] Further, there is also a commercial demand for a method of obtaining two-color images
while retaining the advantages of the thermal transfer recording method as described
above. Accordingly, there have been proposed several techniques for obtaining two-color
images.
[0005] In order to obtain two-color images on plain paper by the thermal transfer recording
method, Japanese Laid-Open Patent Application No. 148591/1981 discloses a two-color
type thermal transfer recording element (transfer material) comprising a substrate
and two heat-fusible ink layers including a high-melting point ink layer A and a low-melting
point ink layer B containing mutually different colorants disposed in this order on
the substrate. When a low thermal input energy is applied to the element, only the
low-melting point layer B is transferred onto plain paper, while when a high thermal
input energy is applied to the element, both the heat-fusible ink layers A and B are
transferred onto the plain paper, so that two-color images can be obtained.
[0006] Further Japanese Laid-Open PatentTApplication No. 64389/1984 discloses a two-color
thermal transfer ink sheet which comprises, on a substrate, an ink layer comprising
an ink which melt-exudes at a lower temperature and another ink which is melt-peeled
at a higher temperature than the melt-exudation temperature.
[0007] In the methods using the above mentioned thermal transfer material, two-color recording
is effected by changing the energy applied to a thermal head at two levels so as to
change the temperature of the ink layers. However, when a high energy is input to
the ink layers to provide a high temperature, a lower temperature portion is formed
at the periphery of a higher temperature portion due to heat diffusion, so that a
bordering of a lower temperature color is formed around the higher temperature printed
image. Further, when a high energy is supplied to a thermal head, it requires a relatively
long time until the thermal head is cooled so that a higher-temperature printed image
is liable to be accompanied with a trailing of a lower-temperature color. Further,
in any of the above methods, there is a constraint that a relatively low melting material
is required for providing an ink to be transferred at a lower temperature, whereby
they give rise to problems such as ground soiling and low storability of the thermal
transfer material.
[0008] As a technique for dissolving the"above-mentioned problems, our search group has
proposed a recording method as disclosed in Japanese Laid-Open Patent Application
No. 137789/1986 (U.S. Patent Application Serial No. 819,497).
[0009] In this recording method, there is employed a thermal transfer material comprising
a support and at least a first ink layer and a second ink layer disposed in this order
on the support, and after heat is applied to the thermal transfer material, a length
of time from the heat application until the separation between the transfer material
and a recording medium is so controlled that the second ink layer selectively, or
both the first and second ink layers are transferred to the recording medium.
[0010] Our research group has further proposed, as a thermal transfer material for use in
such recording method, one as disclosed in Japanese Laid-Open Patent Application No.
295075/1986 and one as disclosed in Japanese Laid-Open Patent Application No. 295079/1986.
[0011] Japanese Laid-Open Patent Application No. 295075/1986 discloses a thermal transfer
material wherein at least one of a first ink layer and a second ink layer is caused
to contain a silicone oil or a fluorine containing surfactant thereby to easily cause
separation between the first and second ink layers. Japanese Laid-Open Patent Application
No. 295079/1986 discloses a thermal transfer material wherein a fine powder layer
being not melted by a heat energy applied for recording is disposed between a first
ink layer and a second ink layer thereby to easily cause separation therebetween.
[0012] The above-mentioned recording method, as disclosed in Japanese Laid-Open Patent Application
No. 137789/1986 (U.S. Patent Application Serial No. 819,497), has solved the problems
of bordering, trailing, etc., in the prior art. In this method, there may be a case
where a material capable of having a relatively high adhesion to a recording medium
for obtaining images of higher quality on the recording medium. In this case, when
the second ink layer is selectively transferred to the recording medium, mixing of
colors is liable to occur because the color of the first ink layer is liable to mix
with images of the second ink layer. Accordingly, in such a case, it is not necessarily
easy to selectively transfer the second ink layer to the recording medium stably and
with excellent reproducibility.
SUMMARY OF THE INVENTION
[0013] A principal object of the present invention is to dissolve the above-mentioned problems
accompanying the prior art and to provide a thermal transfer recording method which
provides clear multi-color images showing good transferability to a'recording medium
and good color separation through a simple process, and which does not necessarily
require a low-melting material having a tendency to decrease the storability of a
thermal transfer material.
[0014] We have discovered that in order to transfer a second ink layer more selectively
in the above recording medium disclosed in Japanese Laid-Open Patent Application No.
137789/1986 (U.S. Patent Application Serial No. 819,497), it is necessary to stably
control the length of time from the energy application until the separation between
a thermal transfer material and a recording medium, with precision at a level of 10
-3 sec. and with high reproducibility.
[0015] As a result of our various experiments based on the above knowledge, it is further
discovered that in order to realize such precise control of separation, there are
never negligible the stability and reproducibility in an extremely little delay in
the separation between the thermal transfer material and the recording medium, which
is counted from the passage of the transfer material across the trailing end of a
heat-applying means such as a thermal head. Such delay is at a level of 10
-3 sec. or less, which has been neglected in the conventional thermal transfer recording
methods for obtaining two-color images.
[0016] Further, we have discovered that in order to realize the stability and reproducibility
at such level of time, a conventional thermal transfer apparatus has been useless
and there has been required a special thermal transfer apparatus capable of applying
a peeling force of above a prescribed magnitude in a direction of from a recording
medium to a thermal transfer material at the time of separation therebetween.
[0017] The thermal transfer recording method according to the present invention has been
provided on the basis of the above discovery, and comprises: providing a thermal transfer
material comprising a support and at least a first ink layer and a second ink layer
disposed in this order on the support,
superposing the transfer material on a recording.medium so that the ink layers contact
the recording medium,
applying energy to the transfer material corresponding to information to be recorded,
and
separating the transfer material from the recording medium in a length of time until
separation counted from the energy application so that the second ink layer is selectively
transferred to the recording medium in a shorter time until separation, and both the
first and second ink layers are transferred to the recording medium in a longer time
until separation;
wherein the thermal transfer material is separated under the action of a peeling force
of not Less than 20 g.f and less than 200 g.f in a direction perpendicular to and
leaving from the surface of the recording medium toward the thermal transfer material,
when the thermal transfer material is peeled off from the recording medium in the
shorter time until separa
- tion.
[0018] These and other objects, features and advantages of the present invention will become
more apparent upon a consideration of the following description of the preferred embodiments
of the present invention taken in conjunction with the accompanying drawings, wherein
like parts are denoted by like reference numerals. In the description appearing hereinafter,
"part(s)" and "%" used for describing quantities are by weight unless otherwise noted
specifically.
BRIEF DESCRIPTION OF THE DRAWINGS
[0019] Figures 1 to 3 and Figures 5 to 7 are respectively schematic sectional views in the
thickness direction of a thermal transfer material; wherein Figure 1 shows a thermal
transfer apparatus for use in the thermal transfer recording method according to the
present invention, Figure 2 shows an enlarged view of the heat-applying portion in
Figure 1, and Figure 3 and Figures 5 to 7 respectively show an example of a thermal
transfer material for use in the present invention.
[0020] Figure 4 is a graph showing a variation of adhesion strength between various layers
with the elapse of time.
DETAILED DESCRIPTION OF THE INVENTION
[0021] Figure 1 is a schematic sectional view for illustrating an embodiment of the thermal
transfer recording method according to the present invention.
[0022] Referring to Figure 1, a thermal transfer material 1 comprises a support and a first
ink layer and second ink layer disposed in this order on the support. The thermal
transfer material is wound off from a supplying core 2a and moved in a direction of
an arrow A, and passes through a heat-applying position at which a thermal head 3
confronts a recording medium 5 such as plain paper disposed on a platen 4. Thereafter,
the thermal transfer material is wound up about a winding core 2b.
[0023] At the heat-applying position, the thermal head 3 contacts or abuts on the support
side of the thermal transfer material 1, while the recording medium 5 contacts or
abuts on the second ink layer side of the thermal transfer material 1. Further, on
the support side of the thermal transfer material 1, at an intermediate position between
the thermal head 3 and the winding core 2b, a control member 6 for controlling the
length of time until separation is disposed movably in a direction of an arrow B,
perpendicular to the surface of the recording medium 5 to be recorded.
[0024] The above-mentioned thermal transfer material 1, the supplying core 2a, the winding
core 2b, the thermal head 3, and the control member 6 are housed in a carriage 7 disposed
movably in a direction of an arrow C.
[0025] By using such apparatus, when the control member 6 does not contact the thermal transfer
material 1, heat energy corresponding to information to be recorded is supplied to
the thermal transfer material 1 by means of the thermal head 3 contacting the support
side of the transfer material 1 moving in the direction of the arrow A. Thereafter,
if the transfer material 1 is immediately peeled off from the recording medium 5 (i.e.,
in a relatively short length of time after the heat application), the second ink layer
of the transfer material 1 is selectively transferred to the recording medium 5 threby
to form a recorded image in the color of the second ink layer (e.g., red) on the recording
medium 5. The above-mentioned "relatively short length of time" may preferably be
0.5 to 10 msec.
[0026] On the other hand, the control member 6 is moved in the direction of the arrow B
so as to be disposed as shown by a dotted line 6a in Figure 1, thereby to press the
transfer material 1 on the recording medium 5, as shown by a dotted line 1a. In this
state, after heat energy is similarly supplied to the transfer material 1, if the
transfer material 1 is peeled off from the recording medium 5 as shown by the dotted
line 1a (i.e., in a relatively long length of time after the heat application), both
the first and second ink layers are transferred to the recording medium 5, thereby
to form a recorded image ordinarily in the color of the first ink layer (e.g., black)
on the recording medium 5. The above-mentioned "relatively long length of time" may
preferably be 30 to 500 msec.
[0027] Incidentally, a pressing force based on the above control member 6 may be sufficient
to make the transfer material 1 contact the recording medium 5, and is not necessarily
a strong pressing force. If the pressing force is too strong, it rather decreases
a running characteristic of the transfer material 1, or causes a problem such as ground
soiling of the recording medium 5.
[0028] Hereinabove, the outline of the thermal transfer recording method according to the
present invention has been described. Now, there will be.explained a peeling force
in the case of selectively transferring the second ink layer in the present invention.
[0029] Figure 2 is an enlarged view of the heat-applying portion in Figure 1.
[0030] Referring to Figure 2, the thermal head 3 presses the thermal transfer material 1
to the recording medium 5 by a pressing force F. The thermal transfer material 1,
immediately after supplied with heat by means of a heater portion 3a of the thermal
head 3, is peeled off at the trailing end 3b of the thermal head 3, at an angle θ
with the recording medium 5 and under a tension T. The angle θ may preferably be 20°
- 70°, more preferably 40° - 60°.
[0031] In this case, if a tension acting in the direction of movement of the thermal transfer
material 1 is represented by T, a peeling force 8 acting in the direction perpendicular
to the surface of the recording medium 5 to be recorded, and of from this surface
to the thermal transfer material 1 (i.e., the component of the tension T along the
above perpendicular direction) is represented by Tsinθ. The magnitude of the peeling
force 8 is required to be 20 g.f (g-force) or more, and less than 200 g.f, and may
be preferably 50 to 150 g.f, more preferably 80 to 120 g.f. The width of the thermal
transfer material 1 may preferably be about 3 to 50 mm. The peeling force per unit
width of the transfer material may preferably be 0.4 to 70 g.f/mm, more preferably
1 to 50 g.f/mm, particularly preferably 1.6 to 40 g.f/mm.
[0032] If the peeling force 8 is less than 20 g.f, it is difficult to precisely control
the length of time from the heat application to the peeling at a level of 10
-3 sec. Therefore, it is impossible to stably cause separation with high reproducibility,
whereby a first ink constituting the first ink layer is liable to be mixed in a recorded
image of the second ink layer (e.g., spots of the first ink is attached to the transferred
second ink layer).
[0033] On the other hand, if the peeling force 8-is 200 g.f or more, the contact pressure
of the thermal transfer material 1 on the thermal head 3 becomes too high thereby
to cause sticking, or the thermal transfer material 1 cannot desirably contact the
recording medium 5 thereby to deteriorate the image quality.
[0034] The magnitude of the peeling force 8 may be controlled or regulated by changing that
of the above-mentioned tension T or the peeling angle θ (i.e,. the angle formed by
the thermal transfer material 1 with the surface of the recording medium 5 to be recorded,
at the trailing end of the thermal head). In order to control the peeling force 8
more stably, it is preferable to regulate the tension T.
[0035] The magnitude of the tension T may be regulated, e.g., by a torque applied to the
winding core 2b in Figure 1. Further, the tension T may be measured, e.g., by means
of a spring scale. More specifically, it may be measured by disposing the spring scale
and the winding core 2b in the same situation so that between the thermal transfer
material 1 and the winding core 2b.
[0036] Hereinbelow, the thermal transfer material for use in the present invention will
be described in further detail.
[0037] Figure 3 is a schematic sectional view in the thickness direction of a basic embodiment
of the thermal transfer material used in the invention. Referring to Figure 3, the
thermal transfer material 1 comprises a support 10 ordinarily in the form of a sheet,
and a first ink layer 11 and a second ink layer 12 formed on and in this order from
the support 1.
[0038] In the thermal transfer material 1 used in the present invention, the relation with
respect to largeness of adhesion (strength) between the adhesion (F2) between the
first ink layer 11 and the second ink layer 12, and the adhesion (F
1) between the first ink layer 11 and the support 10, must be inverted between those
at a high temperature and at a low temperature, e.g., in the course of cooling of
the ink layers after application of heat thereto sufficient to cause thermal transfer
of the .ink layers. For example, when the transfer material 1 is heated, the ink layers
11 and 12 are so constituted that the separation between the first ink layer 11 and
the second ink layer 12 is better than that between the first ink layer 11 and the
support 10 immediately after heating,;and the separation between the first ink layer
11 and the support 10 becomes relatively easier after.a considerable time has passed
from the heating until the separation of the support 10 from a recording medium, i.e.,
at the time when the transfer material 1 is cooled after the transfer material 1 and
the recording medium has been superposed, heated and retained for a substantial time
after heating and before peeling.
[0039] The above mentioned characteristics of the respective layers will be further explained
with reference to Figure 4.
[0040] Incidentally, the adhesion (F
2) between the second and first ink layers and the adhesion (F
1) between the first ink layer and the support are evaluated according to relative
easiness between the separation between the second and first ink layers, and the separation
between the first ink layer and the support, when transfer recording is effected on
a recording medium. Such evaluation of the adhesions is not affected by the form of
separation between ink layers (e.g., whether or not the separation between the second
and first ink layers has occurred strictly at the boundary between these layers, or
whether or not some adhesive layer described hereinafter, if any, remains on the thermal
transfer material).
[0041] Now, referring to Figure 4, the adhesion (F
2) between the first ink layer 11 and the second ink layer 12, and the adhesion (F
1) between the"first ink lyaer 11 and the support 10, change on heating and cooling.
If the second ink layer 12 in Figure 3 is composed of a material showing a large change
in adhesion or cohesion and the first ink layer 11 is composed of a material showing
a small change in adhesion or cohesion, the adhesion F
2 sharply decreases on temperature increase due to heating by a thermal head. As a
result, the adhesion F
2 is weaker than the adhesion F
1 as shown in Figure 4, at a time immediately after heating (i.e., before the temperature
being lowered). Accordingly, if the transfer material is peeled from the recording
medium immediately after the transfer material is heated while the second ink layer
12 thereof being in contact with the recording medium, i.e., at a time t
1 in Figure 4, only the second ink layer 12 is transferred to the recording medium
5.
[0042] In contrast, if the transfer material is peeled from the recording medium at a time
t
2 in Figure 4 when a little time has passed after heating (i.e., the temperature of
the ink layer has been lowered) and the adhesion F
2 is recovered to exceed the adhesion F
1, the first ink layer
11 is transferred together with the second ink layer 12 to the recording medium.
[0043] Accordingly, if the color tones of the first ink layer 11 and the second ink layer
12 are composed to be different from each other in the thermal transfer material,
clear two-color recorded images can be obtained according to the thermal transfer
recording method of the present invention.
[0044] When the color of the first ink layer 11 and the second ink layer 12 are desired
to be obtained substantially as they are, it is preferred to dispose a first ink layer
11 of a dark color such as black and a second ink layer 12 of a brighter color than
that of the first ink layer such as red.
[0045] Further, the first and second ink layers can be made in the same hue but different
in density from each other, whereby two-color images with dense and pale portions
can be obtained in the same manner as described above. Further, the first ink layer
can function as a correcting ink layer by incorporating, e.g., a white pigment having
a strong hiding power therein.
[0046] In the above embodiments explained with reference to Figure 4, the relative adhesions
between the layers after a substantial time after heating are essentially the same
as those before heating. This is, however, not an essential requirement. For example,
in a case where the ink layers are formed by emulsion- coating, the states of the
ink layers after a little while after heating can be different from those of the ink
layers before heating.
[0047] Further, the separation between the'first ink layer 11 and the support 10 need not
necessarily occur at the boundary between them but may occur within the first ink
layer 11.
[0048] Figures 5 to 7 are respectively schematic sectional views in the thickness direction
showing a laminar structure of another embodiment of the thermal transfer material
used in the invention.
[0049] Figure 5 shows a thermal transfer material wherein a first adhesive layer 13a is
disposed between the first ink layer 11 and the support 10, and Figure 6 shows a thermal
transfer material wherein a second adhesive layer 13b is disposed between the second
ink layer 12 and the first ink layer 11.
[0050] The above first adhesive layer 13a may preferably be composed of a material showing
a relatively small change in adhesion on temperature change such as broadly (or gradually)
meltable resins. On the other hand, the above second adhesive layer 13b may preferably
be composed of a material showing a relatively large change in adhesion on temperature
change such as sharply meltable waxes. Such first adhesive layer 13a shows a gradual
change in its strength on temperature change and such second adhesive layer 13b shows
a sharp change in its strength on temperature change. As a result, a variation in
relative adhesions as shown in Figure 4 may be obtained, similarly as in the embodiment
of Figure 3.
[0051] The above first adhesive layer 13a and second adhesive layer 13b may be disposed
in combination, as shown in Figure 7.
[0052] In a case where an adhesive layer is disposed as shown in Figures 5 to 7, it is easier
to select materials constituting the first and second ink layers for obtaining a desired
change in adhesion, and to prevent these ink layers from mixing. Accordingly, such
adhesive layer may preferably be used in order to improve clearness of two-color recorded
images.
[0053] As the support 10 of the thermal transfer material, it is possible to use films of,
e.g., polyester, aramide resin, nylon, polycarbonate, or capacitor paper, preferably
having a thickness of about 3 to 12 µm. Too thick a support is not desirable becuase
the heat conductivity becomes inferior. If a sufficient heat resistance and a strength
are attained, a support may be thinner than 3 µ.
[0054] The structures and compositions of the embodiments shown in Figure 3 and Figures
5 to 7 will be described in more detail.
[0055] The first and second ink layers should preferably contain 1 to 50 % of a colorant
and have a softening temperature within the range of 60 to 180°C. A softening temperature
of the second ink layer 12 below 60°C results in a poor storability and is not preferred.
A softening temperature above 1'80°C provides a poor heat sensitivity and is not preferred.
[0056] On the other hand, the first ink layer 11 in the embodiments shown in Figure 3 and
Figures 5 to 7 can contain up to about 90 %, preferably 1 to 80 %, of a colorant.
[0057] The embodiment shown in Figure 6 will specifically be described hereinbelow.
[0058] Referring to Figure 6, the first ink layer 11 should preferably be heat-fusible but
can be adhesive or tacky at room temperature, can have a remarkably high softening
temperature or can be one lacking a fusibility. On the other hand, the second adhesive
-layer 13b is generally preferred to have a softening temperature of 60 to 180°C.
[0059] The "softening temperature" used herein is a flow initiation temperature as obtained
from an apparent viscosity-temperature curve of a sample ink based on a measurement
by a flow tester (Model: CFT500, available from Shimazu Seisakusho K.K.) under the
conditions of a load of 10 kg, and a temperature increasing rate of 2°C/min.
[0060] It is preferred that the second adhesive layer 13b and the second ink layer 12 are
so composed as to provide a melt viscosity (by a rotary viscometer) as an ink constituting
each layer inclusive of various additives in the range of 10 cps to 1, 000, 000 cps
at a temperature which is 30°C higher than the softening temperature of the respective
layers. Particularly, the second ink layer 12 should preferably have a melt viscosity
of 200 cps or higher at the above specified temperature in order to provide a good
adhesion onto a recording medium such as paper. Further, the adhesive layer 13b should
preferably have a melt viscosity lower than that of the second ink layer 12, respectively,
at a temperature which is 30°C higher than the softening temperature of the second
ink layer 12. By satisfying these conditions, when the transfer medium is peeled off
at time t
1 as shown in Figure 4, a separation within the second ink layer 12 itself, is less
liable to occur, whereby good images can be obtained.
[0061] In a case where the second ink layer 12 is selectively transferred when the thermal
transfer material is peeled off from the recording medium at the time t
1 in Figure 4, the adhesive layer 13b should preferably be so composed as to provide
a softening temperature which is equal to or lower than that of the second ink layer
12. When a recording is conducted by a thermal head, the trailing end portion of the
image portion in the moving direction of the thermal head changes from a printing
temperature to a non-printing temperature. However, during this course of cooling,
if the second ink layer 12 is attached to the recording medium while the strength
of the adhesive layer 13b is still relatively high, the first ink layer 11 can be
transferred along with the second ink layer 12 to unintentionally provide the color
of the first ink layer 11. This phenomenon can be prevented by setting the softening
temperature of the adhesive layer 13b to be equal to or lower than that of the second
ink layer 12 as descirbed above.
[0062] In the thermal transfer material used in the present invention, the total thickness
of the ink layers on the support 10 (i.e., all the layers other than the support 10
inclusive of the adhesive layers) may desirably be 20 µm or less. Further, each of
the first ink layer, the second ink layer and the first and second adhesive layers
should have a thickness in the range of 0.5 to 10 µm.
[0063] It is desirable that the materials constituting the first ink layer 11 and the second
ink layer 12 should be mutually incompatible with each other. This is because the
adhesive layer 13b disposed between the first ink layer 11 and the second ink layer
12 can be crushed by pressing due to a thermal head so as to provide a partial contact
between the first ink layer 11 and the second ink layer 12, and in such a case, the
two-color separation is better retained by using mutually incompatible materials for
the ink layers.
[0064] As a further modification, it is Also effective to provide a heat-resistant layer
on the back surface of the support 10 or between the support 10 and the first ink
layer 11. It is also effective to provide a layer for increasing an adhesion onto
a recording medium on the second ink layer 12. Further, a various functional layer
may be disposed as desired between the respective layers or on the surface. The functional
layer can contain a colorant.
[0065] As one effective example, such a functional layer containing a colorant may be provided
as a layer showing a transferability when it is applied with a higher heat energy
than the first and second ink layers so that it is transferred after the first and
second ink layers to provide an additional color thereof onto the recording medium.
Alternatively, a functional ink layer showing a transferability when applied with
a pressure may be used so as to provide a similar effect.
[0066] As a heating means for the thermal transfer recording method of the present invention,
ordinary heat sources such as infrared rays and laser beam may also be used in place
of a thermal head. Further, in order to provide a conduction heating system, i.e.,
a system wherein a thermal transfer material itself generates a heat due to a current
passing therethrough, a thin layer of a conductive material such as aluminum may be
disposed as a return electrode between the support and the first ink layer, as desird.
[0067] The first ink layer 11, the second ink layer 12 and adhesive layers 13a and 13b may
be formed by using one or more binders selected from the following class and adding
thereto a colorant and other additives as desired. The binder may be selected from
natural waxes such as whale wax, beeswax, lanolin, carnauba wax, candelilla wax, montan
wax and ceresin wax; petroleum waxes such as paraffin wax and microcrystalline wax;
synthetic waxes such as ester wax, low molecular weight polyethylene, Fischer-Tropsch
wax and the like; higher fatty acids such as lauric acid, myristic acid, palmitic
acid, stearic acid, and behenic acid; higher alcohols such as stearyl alcohol and
behenyl alcohol; esters such as fatty acid esters of sucrose and fatty acid esters
of sorbitane; amides such as oleic amide; thermoplastic resins including: homopolymers
of styrene and substituted styrenes such as polystyrene, poly-p-chlorostyrene, and
polyvinyl- toluene; styrene copolymers such as styrene-p-chlorostyrene copolymer,
styrene-propylene copolymer, styrene-vinyltoluene copolymer, styrene-vinylnaphthalene
copolymer, styrene-methyl acrylate copolymer, styrene-ethyl acrylate copolymer, styrene-butyl
acrylate copolymer, styrene-octyl acrylate copolymer, styrene-methyl methacrylate
copolymer, styrene-ethyl methacrylate copolymer, styrene-butyl methacrylate copolymer,
styrene-α-chloromethyl methacrylate copolymer, styrene-acrylonitrile copolymer, styrene-vinyl
methyl ether copolymer, styrene-vinyl ethyl ether copolymer, styrene-vinyl methyl
ketone copolymer, styrene-butadiene copolymer, styreneisoprene copolymer, styrene-acrylonitrile
indene copolymer, styrene-maleic acid copolymer, and styrene-maleic acid ester copolymer;
polymethyl methacrylate, polybutyl methacrylate, polyvinyl chloride, polyvinyl acetate,
polyethylene, ethylene-vinyl acetate copolymer, ethylene-acrylic acid copolymer, polypropylene,
polyester, polyurethane; polyamide, epoxy resin, polyvinyl butyral, polyacrylic acid
resin, rosin, modified rosin, terpene resin, phenolic resin, aliphatic and alicyclic
hydrocarbon resins, and aromatic petroleum resin; homopolymers and copolymers of olefin
such as polyethylene, polypropylene, polyisobutylene, polyethylene wax, oxidized polyethylene,
polytetrafluoroethylene, ethylene-acrylic acid copolymer, ethylene-ethyl acrylate
copolymer and ethylene-vinyl acetate copolymer; and derivatives of these polymers.
[0068] The colorant may be selected from all of the known dyes and pigments including:,carbon
black, Nigrosin dyes, lamp black, Sudan Black SM, Alkali Blue, Fast Yellow G, Benzidine
Yellow, Pigment Yellow, Indo Fast Orange, Irgadine Red, Paranitroaniline Red, Toluidine
Red, Carmine FB, Permanent Bordeaux FRR, Pigment Orange R, Lithol Red 20, Lake Red
Ci Rhodamine FB, Rhodamine B Lake, Methyl Violet B Lake, Phthalocyanine Blue, Pigment
Blue, Brilliant Green B, Phthalocyanine Green, Oil Yellow GG, Zapon Fast Yellow CGG,
Kayaset Y963, Kayaset YG, Smiplast Yellow GG, Zapon Fast Orange RR, Oil Scarlet, Smiplast
Orange G, Orasol Broan B, Zapon Fast Scarlet CG, Aizen Spiron Red BEH, Oil Pink OP,
Victoria Blue F4R, Fastgen Blue 5007, Sudan Blue, and Oil Peacock Blue. Further, metal
powder such as copper powder and aluminum powder or powder of mineral such as mica
may also be used as a colorant. Further, other additives such as plasticizers, mineral
oils, vegetable oils, etc., may also be added.
[0069] The ink layers and adhesive layers having the desired properties as described with
reference to the relative adhesions as shown in Figure 4, may be obtained by appropriately
controlling the properties such as molecular weights, crystallinities, etc., of the
above mentioned materials or appropriately mixing a plurality of the above mentioned
materials.
[0070] The thermal transfer material used in the invention may be obtained by forming the
respective layers by mixing the materials constituting the respective layers and an
organic solvent such as methyl ethyl ketone, xylene and tetrahydrofuran capable of
dissolving the binders and applying the thus formed coating liquids successively on
the supports Alternatively, the so-called hot-melt coating method may be adopted,
including the steps of blending, hot-melting and applying the materials in a molten
state for the respective layers. The materials for the respective layers may be formed
into aqueous emulsions by the addition of a dispersant such as a surfactant, and the
aqueous emulsions may be applied to form the respective layers. Further, the respective
layers of the transfer material may also be formed by using the above mentioned coating
methods in combination, i.e., by using different methods for the respective layers.
[0071] As described hereinabove, according to the present invention, there is provided a
thermal transfer recording method wherein energy is applied to a thermal transfer
material comprising a support and at least a first ink layer and a second ink layer
disposed in this order on the support, thereafter the thermal transfer material is
peeled off from a recording medium in a relatively short length of time until separation
while applying a peeling force of above a prescribed magnitude to the thermal transfer
material.
[0072] According to the thermal transfer recording method of the present invention, the
second ink layer is stably transferred to the recording medium with excellent reproducibility
by precisely controlling the above length of time until separation at a level of 10
-3 sec., whereby beautiful two-color transferred images of good color separation are
provided.
[0073] Hereinbelow, the present invention will be explained more specifically while referring
to specific examples of practice. Incidentally, the number-average molecular weight
Mn of a sample such as oxidized polyethylene was measured in the following manner.
[Molecular Weight Measurement]
[0074] The VPO method (Vapor Pressure Osmometry Method) is used. A sample of oxidized polyethylene
is dissolved in a solvent such as benzene at various concentrations (C) in the range
of 0.2 to 1.0g/100 ml to prepare several solutions. The osmotic pressure (π/C) of
each solution is measured and plotted versus the concentration to prepare a concentration
(C)-osmotic pressure (π/C) curve, which is extrapolated to obtain the osmotic pressure
at the infinite dilution (π/C)
0. From the equation of (π/C)
0 = RT/Mn, the number-average molecular weight Mn of the sample is derived.
Example 1
[0075]
[0076] (The amounts of aqueous dispersions for providing an ink formulation in this example
and the other examples are all expressed based on their solid contents.)
[0077] The above components were sufficiently mixed to prepare an ink 1. The ink 1 was applied
on a 6 µ-thick PET (polyethylene terephthalate) film and dried at 70°C to form:a 2
µ-thick first ink layer.
[0078] An ink 2 having the above composition was applied on the above prepared first ink
layer and water was evaporated thereform to leave a 1 µm-thick adhesive layer of carnauba
wax.
[0079] The above components were sufficiently mixed to prepare an ink 3, which was applied
on the above prepared adheisve layer and dried at 80°C to form a 2 µm-thick second
ink layer, whereby a thermal transfer material (I) having a structure as shown in
Figure 6 was obtained.
Example 2
[0081] The above components were respectively sufficiently mixed to prepare inks 4, 5, 6
and 7.
[0082] These inks 4, 5,6 and 7 were successively applied and dried on a 6 µm-thick PET film
to form a 1 µm-thick first adhesive layer, a 2 µm-thick first ink layer, a 1 µm-thick
second adhesive layer, and a 2 µm-thick second ink layer, whereby a thermal transfer
material (II) having a sturcture as shown in Figure 7 was obtained.
Example 3
[0084] The above components were respectively sufficiently mixed to prepare inks 8, 9 and
10.
[0085] Separately, an addition type silicone resin for release paper was applied at a rate
of 0.3 g/m
2 on the back side of a 3.5 µm-thick PET film support and dried at 70°C to provide
a heat-resistant protective layer.
[0086] On the reverse side from the protective layer of the thus prepared back-coated PET
film, the above inks 8, 9 and 10 were successively applied and dried to form a 1 pm-thick
first adhesive layer, a 2 µm-thick first ink layer and a 2 µm-thick second ink layer,
whereby a thermal transfer material (III) having a structure as shown in Figure 5
was obtained.
[0087] The thus prepared thermal transfer materials (I) - (III) were respectively cut into
an 6 mm-wide tapes and used for recording by means of a thermal transfer recording
apparatus for an English typewriter (Typestar 6, mfd. by Canon K.K.). Referring to
Figure 1, as a thermal head 3, one prepared by Rohm K.K., having a length from the
center of the heat generating part 3a to the trailing end 3b (as shown in Figure 2)
of 350 µm was used. A carriage loading the thermal head 3 and a thermal transfer material
ribbon 1 was moved in the direction of an arrow C, of which moving velocity was 50
mm/sec. Accordingly, the time (t
1 in Figure 4) from heating until the peeling-off of the ink ribbon from a recording
medium was about 7 msec in the rapid peeling-off mode. In order to delay the time
of the peeling-off, a control member 6 for controlling the peeling-off was disposed
at about 5 mm (i.e., i = 5 mm as shown in Figure 1) after the trailing end 3b of the
thermal head (i.e., downstream side of the trailing end 3b with respect to the moving
direction of the thermal transfer material 1).
[0088] As a result, when the control member 6 was moved toward the recording medium, the
delayed time of peeling-off (t
2 in Figure 4) was about 100 msec after the heating. Incidentally, as a preliminary
test, the position of the control member 6 was changed in different ways, whereby
it was confirmed that the result of the recording was not substantially different
from the case of ℓ = 5 mm, if it was disposed at a position from 2 mm to 20 mm (i.e.,
£ = 2 - 20 mm) after the trailing end of the thermal head.
[0089] Where the transfer recording was conducted on plain paper by the use of the thermal
transfer materials (I), (II) and (III), while changing a peeling force 8 (shown in
Figure 2) into various values such as 15, 20, 30, 100, 190, 200, and 220 g.f, blue
images were obtained when the transfer material was peeled rapidly and black images
were obtained when the transfer material was peeled at the delayed time.
[0090] However, in case where the peeling force 8 was 15 g.f, black color was mixed with
blue images, whereby clear blue images were not obtained. To the contrary, in a case
where the peeling force 8 was 20, 30, 100, or 190 g.f, clear blue images were obtained.
Further, in a case where the peeling force 8 was 200 or 220 g.f, sticking of the thermal
transfer material to the thermal head became marked as the peeling force became larger,
whereby only images of low quality were obtained. Incidentally, when the peeling force
8 was changed in such a manner, black images obtained were not substantially different
from each other.