Information
-
Patent Grant
-
6734382
-
Patent Number
6,734,382
-
Date Filed
Wednesday, May 28, 200321 years ago
-
Date Issued
Tuesday, May 11, 200420 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Rader, Fishman & Grauer PLLC
-
CPC
-
US Classifications
Field of Search
US
- 029 622
- 200 5 A
- 200 512
- 200 517
- 200 308
- 200 310
- 200 311
- 200 313
- 200 314
- 200 341
- 200 345
-
International Classifications
-
Abstract
A method for forming an indicator portion on a push switch such as a pushbutton switch or a membrane switch, the indicator portion being excellent in terms of design property and image quality and allowing fine picture patterns, designs, etc. that are difficult to be reproduced with conventional printing systems to be represented with high resolution, and to provide a push switch having the indicator portion. In order to form the indicator portion, in which a color design image such as a letter, a pattern, design etc is indicated, on the push switch, there are performed the following steps of: forming a colorant layer by printing a color design image on a base sheet by a printer; transferring the colorant layer to a transfer resin through an adhesive, the transfer resin constituting a surface of the push switch; and forming the indicator layer on the transfer resin by peeling off the base sheet and using the colorant layer as the indicator layer.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a push switch, such as a pushbutton switch used in the operation portion of an electronic apparatus, a portable device, a vehicle-mounted switch, a remote controller etc., or a membrane switch used in an electronic apparatus, for example, as a thin switch input device.
More specifically, the present invention relates to a method for forming, on a pushbutton switch, an indicator portion in which color design images such as letters, patterns, and designs are indicated, and to a pushbutton switch having the indicator portion.
Also, the present invention relates to a method for forming, on a membrane switch, an indicator portion in which color design images such as letters, patterns, and designs are indicated, and a membrane switch having the indicator portion.
2. Description of the Related Art
Pushbutton switches used in electronic apparatuses such as portable telephones have an indicator layer for the indication of color design images such as letters, numerals, figures, symbols, and design patterns. Such an indicator layer is formed by printing shapes corresponding to letters, symbols, or the like on a key top mainly formed of a resin, by screen printing, pad printing, or the like.
However, with the recent trend toward miniaturization and an increase in the functions of electronic apparatuses, key tops of pushbutton switches are also becoming increasingly smaller in size. Thus, there is a need to enable indication of as many letters or numerals as possible, or complex figures, symbols, design patterns, etc. formed using multiple colors, on a small key top having a limited space. Consequently, with the conventional methods such as screen printing or pad printing, it has become increasingly difficult to form an indicator layer which is capable of high resolution, the resolution being a measure of the meticulousness of a drawing or the smoothness of an image, and on which fine, sharp designs are rendered. Further, the screen printing and the pad printing require the use of a printing plate for each color, so that the number of printing steps increases as the number of colors for printing increases, thus necessitating sophisticated printing techniques that enable a fine positional adjustment, or measures for preventing the intrusion of contaminants. Further, when changing the design of a pushbutton switch, it is necessary to prepare new printing plates. Thus, the printing plates are prepared in accordance with colors required for each product, so that a great deal of time, labor, and costs is involved in storing and maintaining the printing plates. Due to the reasons described above, conventional methods based on printing, for example screen printing and pad printing, have proved inadequate to quickly respond to the diversity of designs and shorter life cycles, making it impossible to meet such demands as the simplification of the production steps, reduction in cost, and higher resolution.
In contrast, as an alternative method for preparing an indicator layer on a pushbutton switch to the conventional printing methods, there is a method of bonding onto a key top a photographic sheet formed on a resin sheet by graphic photo-printing using a printer. A similar technique is described in JP 2000-231849 A. However, with the above method, it is necessary to perform a post-processing of cutting the photographic sheets along the outer peripheral configurations of individual key tops using a carbon dioxide laser or a punching edge. In addition, because a rather thick photographic sheet is cut, burrs are easily produced on the cut surfaces. Further, the photographic sheet is integrated with the key top, making the above method unsuitable for dealing with the demand for reduced thickness.
Membrane switches are used as thin switch input devices in, for example, electronic apparatuses. An example of conventional membrane switches is shown in
FIGS. 17 and 18
. Such a conventional membrane switch, denoted
100
, commonly has a construction as shown in
FIGS. 17 and 18
. That is, the membrane switch is generally composed of a front-side film, or sheet material
101
that is exposed to the outward appearance of a not-shown electronic apparatus, a back-side film, or sheet material
102
received within the inner portion of the electronic apparatus, and a spacer
103
arranged between the two film materials. Formed on the two sheet materials
101
and
102
are contact electrodes
101
a
and
102
a
, respectively. When pressed from above, the contact electrode
101
a
of the front-side sheet material
101
is brought into conducting contact with the contact electrode
102
a
of the back-side sheet material
102
by way of a through hole
103
a
formed in the spacer
103
. Establishing such conducting contact makes it possible to attain a predetermined switch function of the electronic apparatus. Advantages of the membrane switch
100
described above reside in the simplicity of its construction and its small thickness. As such, the switch is employed in various apparatuses as a switch input device of an electrical apparatus for which there is a particularly strong demand for miniaturization.
In such a membrane switch
100
, in general, letters, numerals, symbols, figures etc. are colors for indication or a colored exterior film
104
is bonded onto a portion thereof which is exposed to the outward appearance of the electronic apparatus. Such an exterior film
104
is typically obtained by screen-printing a coating material onto a resin film. However, with screen printing, it is necessary to prepare a printing plate for each color, which places a large burden in terms of both labor and cost. Further, when changing the design, it is necessary to prepare all new printing plates from scratch, which leads to a further increase in labor and cost. To overcome the above problem, there is proposed a method for forming the exterior film
104
which includes: preparing a design by a personal computer; printing the design on a base sheet (not shown) such as paper or a PET film using a commercially available color printer to thereby prepare the external film
104
; and stacking the exterior film
104
on the front-side film material
101
using an adhesive tape or the like (for a similar technique, see Japanese Utility Model Application Laid-open No. Hei 5-90762).
However, with the above-described method, it is also necessary to perform a step of cutting the exterior film
104
along the outer peripheral configurations of individual membrane switches using a carbon dioxide laser or a punching edge. In addition, burrs are easily generated resulting from the cutting step. Further, with the above-described method, it is commonly necessary to provide a protection sheet for protecting the printing surface subjected to printing using a color printer, which leads to a considerable increase in the overall thickness inclusive of the thickness of the base sheet. If the resulting structure is integrated as a part of the membrane switch, the flexibility of a portion subjected to pressing operation with, for example fingers is impaired, resulting in such problems that the operational feel as a membrane switch is degraded, on/off operation of the switch is not properly effected by the pressing operation, and the like. Therefore, the above-described method is not suitable for application to membrane switches whose structural advantages reside in their small thicknesses. On the other hand, to avoid the problem described above, the printing surface subjected to printing by a color printer may be bonded onto a portion that is exposed to the outward appearance of the electronic apparatus. With this arrangement, however, the color design image is viewed from the back (from the side opposite to the printing surface), so that the image appears distorted. Thus, it is often difficult to view the image with good reproducibility while maintaining high resolution.
SUMMARY OF THE INVENTION
The present invention enables forming an indicator portion having an excellent design image, on a push switch such as a pushbutton switch or a membrane switch.
That is, an object of the present invention is to inexpensively provide an indicator portion for pushbutton switch which enables indication of a large number of letters, symbols, or complex, fine picture patterns, design etc. with clarity and high resolution, allows a reduction in the number of manufacturing steps without requiring sophisticated printing techniques etc., and results in excellent design property and image quality.
Another object of the present invention is to provide an indication portion for a membrane switch, in which letters, symbols, or patterns etc. serving as input elements exposed to the outward appearance of an apparatus has high resolution while exhibiting excellent design property and image quality, and a membrane switch having the indicator portion.
To achieve the above objects, according to the present invention, there is provided an indicator portion forming method for a push switch, in which an indicator portion indicating a color design image such as a letter, a pattern, or a design is formed on the push switch, the method including: forming a colorant layer by printing a color design image on a base sheet by a printer; transferring the colorant layer to a transfer resin through an adhesive, the transfer resin constituting a surface of the push switch; and forming an indicator layer on the transfer resin by peeling off the base sheet and using the colorant layer as the indicator layer.
According to the indicator portion forming method for a push switch, the method performs the steps of: forming a colorant layer by printing a color design image on a base sheet by a printer; transferring the colorant layer to a transfer resin through an adhesive, the transfer resin constituting a surface of the push switch; and forming an indicator layer on the transfer resin by peeling off the base sheet and using the colorant layer as the indicator layer. As a result, an inexpensive, high-quality indicator portion can be obtained which allows a large number of letters, numerals, figures, symbols etc., or patterns of complex configurations with multiple colors to be indicated with sharp clarity on a small area of the push switch surface and which can be produced in a stable manner without relying on the skill of an operator.
Further, according to the present invention, there is provided an indicator portion forming method for a push switch, in which the push switch is a pushbutton switch having a key top made of resin and the transfer resin is a key top main body of the pushbutton switch. According to the indicator portion forming method for a push switch described above, the base sheet is peeled off after the colorant layer is transferred to the transfer resin. As a result, a pushbutton-switch key top having a thin indicator layer can be obtained. Further, since the method does not involve cutting or punching out the base sheet, the pushbutton-switch key top obtained is of high quality with little generation of burrs. Thus, a pushbutton switch having such a key top is obtained.
Further, according to the present invention, the push switch is a membrane switch including: an operation sheet which is provided with an indicator layer indicating a color design image such as a letter, a pattern, or a design and on which a depressing operation is performed; and a switch portion having contact electrodes provided in opposed positions, the switch portion executing a predetermined switch function when the contact electrodes, that are insulated from each other, are brought into electrical connection by the depressing operation on the operation sheet, and the transfer resin is a translucent film constituting a part of the operation sheet.
When the push switch is formed as a membrane switch, an indicator layer having excellent resolution representing the meticulousness of a drawing or the smoothness of an image can be formed on the membrane switch stably and inexpensively without using complex printing techniques. As a result, a high-quality membrane switch can be obtained. In particular, since the base sheet is peeled off in the course of forming the operation sheet of the membrane switch, the operation sheet can be reduced in thickness, thereby making it possible to obtain a membrane switch with a good operating feel and an excellent operational accuracy. Further, the colorant layer is transferred, so that the resulting membrane switch has an indicator layer of high quality, which can be formed without requiring cutting or punching out the base sheet after the transfer process and in which few burrs are produced.
Further, according to the present invention, there is provided an indicator portion forming method for a push switch, in which the transfer resin is formed of a transparent or semi-transparent resin and the colorant layer is transferred to a back surface of the transfer resin.
According to the indicator portion forming method for a push switch, the transfer resin is formed of a transparent or semi-transparent resin and the colorant layer is transferred to the back surface of the transfer resin. As a result, even when the colorant layer is transferred, a color design image outputted by a printer can be viewed from the front side (the printing surface side), thereby making it possible to form an image such as a letter, a symbol, a pattern etc. having high resolution and high appearance quality. Where the image is viewed from the side opposite to the printing surface side, ink smears onto the base sheet or a receiving layer and the like formed on the base sheet, so that there are cases where a surface with ink smeared thereon is viewed. Therefore, it is considered that viewing an image from the printing surface side results, in many cases, in a resolution superior to that obtained when the image is viewed from the side opposite to the printing surface.
Further, according to the present invention, there is provided an indicator portion forming method for a push switch, in which the base sheet has an image bearing layer and the colorant layer is formed by printing a color design image on the image bearing layer by using a printer.
According to the indicator portion forming method for a push switch, the base sheet has an image bearing layer and the colorant layer is formed by printing a color design image on the image bearing layer by using, a printer, thereby making it possible to reproduce an image having excellent resolution with excellent adherence and absorption of a colorant such as ink or toner. Further, in addition to having an indicator layer of excellent water resistance and weatherability in which the colorant is protected with the image bearing layer, because the colorant layer can be transferred onto the transfer resin side with accuracy, the push button obtained has high appearance quality and is excellent in terms of resolution and image quality. In particular, if the image bearing layer is formed of a porous material having a binding phase composed of inorganic particles that are bound by a binder resin, a push switch is obtained which is excellent in terms of transfer property with little generation of burrs even when removing the base sheet, as well as in terms of ink absorption, storage stability of the indicator layer, and appearance quality of the obtained image. Further, if the image bearing layer is provided with a large number of longitudinal pores opening in a direction normal to the base sheet surface, the image bearing layer is readily exfoliated upon the transfer and is therefore excellent in terms of transferability. In particular, when an ink jet printer is used, ink absorption is effected instantaneously due to the strong ink absorption force afforded by the ink jet printer, making it possible to obtain a push switch allowing high appearance quality of the obtained image with no running of ink.
Further, according to the present invention, there is provided an indicator portion forming method for a push switch, the method including forming an auxiliary coloring layer for adding such colorations as metallic colors like gold, silver etc., or a white color.
According to the indicator portion forming method for a push switch, the method includes performing the step of forming the auxiliary coloring layer for adding such colorations as metallic colors like gold, silver etc., or a white color. Therefore, an image having colorations such as metallic colors like gold, silver etc, or white, pearl etc., which are difficult to reproduce with a color printer that typically uses CMYK ink, can be easily formed, whereby an indicator portion with good color reproducibility which is excellent in terms of image quality and design can be obtained. In particular, it is possible to perform the step of forming an auxiliary coloring layer, which serves to add such colorations as metallic colors like gold, silver etc., or a white color, on a transfer resin or on a colorant layer before or after the colorant layer is transferred onto the transfer resin.
Further, according to the present invention, there is provided an indicator portion forming method for a push switch, in which the adhesive is a transparent or semi-transparent hot-melt adhesive, and the transfer of the colorant layer is effected by thermal transfer.
According to the indicator portion forming method for a push switch, the transfer of the colorant layer is effected by thermal transfer using a transparent or semi-transparent hot-melt adhesive, whereby the curing time of the adhesive is shortened and the transfer process is completed instantaneously to achieve good operability and high productivity, and further high operational efficiency is attained since there is no need to additionally provide a step for curing the adhesive. Additionally, the method ensures high quality, little generation of burrs etc., and excellent yield since it allows a desired portion to be transferred onto the transfer resin with accuracy. Further, a push switch having the indicator portion that is obtained by the above-described method is formed by using a hot-melt adhesive, so that it is excellent in terms of humidity resistance and storage stability without causing any change in its strength etc. over time. Further, the adhesive used is a transparent or semi-transparent adhesive, so that an illuminated push switch can be obtained which can sufficiently transmit light with no loss of clarity of an image formed on the indicator layer.
Further, according to the present invention, there is provided an indicator portion forming method for a push switch, the method including printing a color design image by using a printer employing an ink jet printing system.
According to the indicator portion forming method for a push switch, an ink jet printer is used as the printer, whereby full color representation and high speed printing are facilitated, thus allowing instantaneous imaging of color design data. Further, there can be obtained an indicator portion realizing a near-photograph image quality and excellent resolution. Further, ink for the ink jet printer is transferred while remaining infiltrated in the porous material, whereby a push switch having an indicator layer that is excellent in terms of weatherability and color developability can be obtained.
Further, according to the present invention, there is provided a push switch having an indicator portion indicating a color design image such as a letter, a pattern, a design etc., characterized by including an indicator layer on a surface of the push switch, the indicator layer being obtained by printing the color design image through an adhesive layer by using a printer.
According to the, push switch, the indicator layer, which is obtained by printing a color design image through an adhesive layer by using a printer, is provided on a surface of the push switch. Therefore, a push switch is obtained which allows a large number of letters, numerals, symbols etc, or patterns of complex configurations with multiple colors to be indicated with sharp clarity and at high resolution on a small area of the push switch surface.
Further, according to the present invention, the push switch may be used as a pushbutton switch having a key top made of resin. Also, according to the present invention, the push switch may be used as a membrane switch including: an operation sheet which is provided with an indicator layer for indicating a color design image such as a letter, a pattern, or a design and on which a depressing operation is performed; and a switch portion having contact electrodes provided in opposed positions, the switch portion executing a predetermined switch function when the contact electrodes that are insulated from each other are brought into conduction by the depressing operation on the operation sheet.
If the push switch is used as a pushbutton switch or a membrane switch, the pushbutton switch or the membrane switch thus obtained has an indicator portion capable of indicating a large number of letters, numerals, symbols etc., or patterns of complex configurations with multiple colors on a surface of the pushbutton switch or the membrane switch. Further, the indication portion can be formed to have a small thickness, so that when it is applied to a membrane switch, there is obtained a membrane switch that provides good operating feel with respect to a depressing operation with no loss of the flexibility of the operation sheet that is subjected to displacement upon the depressing operation.
Further, according to the present invention, there is provided a push switch to be used as a membrane switch in which the operation sheet constitutes a part of the switch portion and contact electrodes are formed on the operation sheet.
According to the membrane switch, the operation sheet constitutes a part of the switch portion, so that there is no need to join the operation sheet having an indicator layer onto the switch portion executing the switch function, and the resulting absence of a joint portion allows a corresponding reduction in layer thickness. Further, the contact electrodes are formed on the operation sheet, so that a flexible film having the contact electrodes provided thereon need not be provided separately from the operation sheet. Therefore, a reduction in layer thickness is achieved as compared with the case where the operation sheet is laminated on the flexible film, whereby a membrane switch is obtained which provides an excellent operating feel with respect to a depressing operation with hardly any no loss of the flexibility of the operation sheet that is subjected to displacement upon the depressing operation.
Further, if the front surface of the push switch is formed of a translucent resin and the indicator layer is formed on the back surface of the translucent resin, a color design image printed by a printer can be viewed from the front side (the printing surface side), thereby making it possible to form an image such as a letter, a symbol, a pattern etc. having high resolution and high appearance quality. Further, if the indicator layer is obtained by printing it on a base sheet having a porous image bearing layer and impregnating ink into the image bearing layer, an image of excellent resolution can be reproduced which is excellent in terms of ink absorption and formed of dots that are closer to regular circles. Further, in addition to having an indicator layer of excellent water resistance and weatherability in which the colorant constituting ink is protected with the image bearing layer, because the colorant layer can be transferred onto the transfer resin side with accuracy, the push button obtained has high appearance quality and is excellent in terms of resolution and image quality. In particular, if the image bearing layer is formed of a porous material having a binding phase composed of inorganic fine particles that are bound by a binder resin, a push switch is obtained which is excellent in terms of transfer property with little generation of burrs even when removing the base sheet, as well as in terms of ink absorption, storage stability of the indicator layer, and appearance quality of the obtained image. Further, if the image bearing layer is provided with a large number of longitudinal pores opening in a direction normal to the base sheet surface, the image bearing layer is readily exfoliated upon the transfer and is therefore excellent in terms of transferability.
Further, according to the present invention, the push switch may further have an auxiliary coloring layer for adding such colorations as metallic colors like gold, silver etc., or a white color. If the auxiliary coloring layer for adding such colorations as metallic colors like gold, silver etc., or a white color is provided, an image having colorations such as metallic colors like gold or silver, white, pearl etc., which are difficult to reproduce with a color printer that typically uses CMYK ink, can be indicated with sharp clarity, whereby the obtained pushbutton switch has good color reproducibility and is excellent in terms of image quality and design.
Further, if the adhesive layer is formed of a hot-melt adhesive, there can be obtained a push switch realizing near-photograph image quality and excellent resolution.
Further, according to the present invention, there is provided a so-called illuminated push switch in which the respective layers constituting the push switch are translucent so that light exiting from an inner light source can be transmitted therethrough to the exterior for illumination. According to the push switch, the light from the inner light source is transmitted through the push switch to the exterior for illumination, thereby realizing improved decorative property and improved visibility at night or in a dark place.
The foregoing description of the present invention should not be construed restrictively. The objects, advantages, features, and uses of the invention will become more apparent from the following description given with reference to the accompanying drawings. Further, it is to be understood that various modifications made without departing from the gist of this invention fall within the scope of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
In the accompanying drawings:
FIG. 1
is a longitudinal sectional view of a pushbutton switch according to Embodiment 1 of the present invention;
FIGS. 2A through 2E
are longitudinal sectional views showing respective steps of manufacturing a key top for the pushbutton switch according to Embodiment 1 of the present invention;
FIG. 3
is a longitudinal sectional view of a pushbutton switch according to Embodiment 2 of the present invention;
FIGS. 4A through 4E
are longitudinal sectional views showing respective steps of manufacturing a key top for the pushbutton switch according to Embodiment 2 of the present invention;
FIG. 5
is a longitudinal sectional view of a pushbutton switch according to Embodiment 3 of the present invention;
FIGS. 6A through 6E
are longitudinal sectional views showing respective steps of manufacturing a key top for the pushbutton switch according to Embodiment 3 of the present invention;
FIG. 7
is a longitudinal sectional view of a pushbutton switch according to Embodiment 4 of the present invention,
FIGS. 8A through 8E
are longitudinal sectional views showing respective steps of manufacturing a key top for the pushbutton switch according to Embodiment 4 of the present invention;
FIG. 9
is a flowchart that compares the indicator portion forming method for a pushbutton switch of the present invention and that for a pushbutton switch of the prior art;
FIG. 10
is a longitudinal sectional view of a membrane switch according to Embodiment 5 of the present invention;
FIGS
11
A through
11
D are longitudinal sectional views showing respective (first half) steps of manufacturing a key top for the membrane switch according to Embodiment 5 of the present invention;
FIGS. 12A through 12C
are longitudinal sectional views showing respective (latter half) steps of manufacturing a key top for the membrane switch according to Embodiment 5 of the present invention;
FIG. 13
is a longitudinal sectional view showing the step of forming an auxiliary coloring layer on an operation sheet;
FIG. 14
is a longitudinal sectional view of a membrane switch according to Embodiment 5 of the present invention;
FIG. 15
is a flowchart that compares the indicator portion forming method for a membrane switch of the present invention and that for a membrane switch of the prior art;
FIG. 16
is a plan view of a push switch according to an embodiment of the present invention;
FIG. 17
is an exploded perspective view of a conventional membrane switch; and
FIG. 18
is a longitudinal sectional view of the conventional membrane switch.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
A push switch of the present invention may be implemented as one of: a pushbutton switch obtained by joining together a key pad, which is placed on a circuit board having contact electrodes and formed of a rubber-like elastic body, and a key top made of a resin; and a membrane switch including an operation sheet subjected to depressing operation and provided with an indicator layer indicating color design images such as letters, patterns, and designs, and a switch portion having contact electrodes that are arranged in opposed positions and executing a predetermined switch function when the contact electrodes that are insulated are brought into conduction with each other by the depressing operation on the operation sheet. Hereinbelow, a description will be given of each of the embodiment in which the invention is implemented as a pushbutton switch having a key top of a hard resin and the embodiment in which the switch is implemented as a membrane switch. Where no difference exits between the both embodiments, a redundant description will be omitted.
(1) Layer Structure and Manufacturing Method
(A) “Pushbutton Switch”
A pushbutton switch of the present invention will be described with reference to the drawings. First, a description will be given of a layer structure and a manufacturing method for a key top of the pushbutton switch.
A key top for pushbutton switch is generally formed by laminating function layers such as an indicator layer, an auxiliary coloring layer, and an adhesive layer for joining those two layers, on the front or back surface of a key top main body formed of a resin. However, the key top may take several different embodiment modes according to differences in relative arrangement of the respective layers.
Embodiment 1
FIG. 1
is a longitudinal sectional view of a pushbutton switch
10
that uses a pushbutton-switch key top
11
according to Embodiment 1 of the present invention. On the back surface
12
a
of a key top main body
12
formed of a transparent or semi-transparent resin, an indicator layer
13
for indicating letters, symbols etc. and having transferred thereon a colorant layer obtained by batch output of color design data, and an auxiliary coloring layer
14
for adding such colorations as metallic colors like gold, silver etc. or a white color are laminated through an adhesive layer
15
. The pushbutton-switch key top
11
is integrated with a key pad
17
formed of a rubber-like elastic body by using an adhesive
16
, thus forming the pushbutton switch
10
.
The manufacture of the pushbutton-switch key top
11
according to Embodiment 1 is performed as follows. First, using an output device (not shown) such as a printer capable of performing batch output of color design data, a color design image is printed on a base sheet
19
to form a colorant layer
18
(FIG.
2
A). Next, the adhesive
15
is coated on the front surface of the colorant layer
18
or on the back surface
12
a
of the key top main body
12
(FIG.
2
B). Thereafter, the base sheet
19
is contact-bonded to the key top main body
12
(FIG.
2
C), thereby transferring the colorant layer
18
onto the key top main body
12
from the base sheet
19
. Then, the base sheet
19
is peeled off (FIG.
2
D). The auxiliary coloring layer
14
is coated on the indicator layer
13
that is transferred and formed on the key top main body
12
(FIG.
2
E), thus obtaining the pushbutton-switch key top
11
. The key pad
17
is bonded to the obtained pushbutton-switch key top
11
, thereby obtaining the pushbutton switch
10
.
Embodiment 2:
FIG. 3
is a longitudinal sectional view of a pushbutton switch
20
that uses a pushbutton-switch key top
21
according to Embodiment 2 of the present invention. Coated on the front surface
22
a
of a key top main body
22
made of a resin is an auxiliary coloring layer
24
, on which an indicator layer
23
is laminated through an adhesive layer
25
. The pushbutton-switch key top
21
is integrated with a key pad
27
formed of a rubber-like elastic body by using an adhesive
26
, thus forming the pushbutton switch
20
.
The manufacture of the pushbutton-switch key top
21
according to Embodiment 2 is performed as follows. The process for forming the colorant layer
28
is the same as that of Embodiment 1 (FIG.
4
A). In Embodiment 2, first, the auxiliary coloring layer
24
is formed by coating on the front surface
22
a
of the key top main body
22
(FIG.
4
B). Next, the adhesive
25
is coated on the auxiliary coloring layer
24
or the colorant layer
28
(FIG.
4
C). Thereafter, a base sheet
29
is contact-bonded to the key top main body
22
(FIG.
4
D), thereby transferring the colorant layer
28
onto the key top main body
22
from the base sheet
29
. Then, the base sheet
29
is peeled off (FIG.
4
E). Thus, the pushbutton-switch key top
21
is obtained which has the indicator layer
23
provided on the front surface side of the key top main body
22
. The key pad
27
is bonded to the obtained pushbutton-switch key top
21
, thereby obtaining the pushbutton switch
20
.
Embodiment 3:
FIG. 5
is a longitudinal sectional view of a pushbutton switch
30
that uses a pushbutton-switch key top
31
according to Embodiment 3 of the present invention. An indicator layer
33
is laminated through an adhesive layer
35
on the front surface
32
a
of a key top main body
32
made of a resin. An auxiliary coloring layer
34
is provided on the back surface
32
b
of the key top main body
32
. The pushbutton-switch key top
31
is integrated with a key pad
37
formed of a rubber-like elastic body by using an adhesive
36
, forming the pushbutton switch
30
.
The manufacture of the pushbutton-switch key top
31
according to Embodiment 3 is performed as follows. The process for forming the colorant layer
38
is the same as those of Embodiments 1 and 2 (FIG.
6
A). In Embodiment 3, the auxiliary coloring layer
24
is formed by coating on the back surface
32
b
of the key top main body
32
(FIG.
6
B). The adhesive
35
is coated either on the front surface
32
a
of the key top main body
32
or on a colorant layer
38
(FIG.
6
C). Thereafter, a base sheet
39
is contact-bonded to the key top main body
32
(FIG.
6
D), thereby transferring the colorant layer
38
onto the key top main body
32
from the base sheet
39
. Then, the base sheet
39
is peeled off (FIG.
6
E). Thus, the pushbutton-switch key top
31
has the indicator layer
33
provided on the front surface
32
a
side of the key top main body
32
. The key pad
37
is bonded to the obtained pushbutton-switch key top
31
, thereby obtaining the pushbutton switch
30
.
Embodiment 4:
FIG. 7
is a longitudinal sectional view of a pushbutton switch
40
that uses a pushbutton-switch key top
41
according to Embodiment 4 of the present invention. An indicator layer
43
and an auxiliary coloring layer
44
are laminated through an adhesive layer
45
on the front side
42
a
of a key top main body
42
made of a resin. The pushbutton-switch key top
41
is integrated with a key pad
47
formed of a rubber-like elastic body by using an adhesive
46
, thus forming the pushbutton switch
40
.
The manufacture of the pushbutton-switch key top
41
according to Embodiment 4 is performed as follows. The process for forming the colorant layer
48
is the same as those of Embodiments 1 through 3 (FIG.
8
A). In Embodiment 4, the auxiliary coloring layer
44
is then laminated by coating on the colorant layer
48
(FIG.
8
B). Then, the adhesive
45
is coated on the front side
42
a
of the key top main body
42
or on the auxiliary coloring layer
44
(FIG.
8
C). Thereafter, a base sheet
49
is contact-bonded to the key top main body
42
(FIG.
8
D), thereby transferring the colorant layer
48
onto the key top main body
42
from the base sheet
49
. Then, the base sheet
49
is peeled off (FIG.
8
E). Thus, the pushbutton-switch key top
41
is obtained. The key pad
47
is bonded to the obtained pushbutton-switch key top
41
, thereby obtaining the pushbutton switch
40
.
Other Embodiments:
In addition to the base sheet
19
,
29
,
39
,
49
on which surface treatment is not performed, a release layer can be provided for improving separation between the base sheet
19
,
29
,
39
,
49
and the respective colorant layer
18
,
28
,
38
,
48
, or a receiving layer for allowing the colorant layer to be neatly printed may be also formed on the base sheet
19
,
29
,
39
,
49
. Further, the auxiliary coloring layer
14
,
24
,
34
,
44
may not be provided unless particularly required. In this case, if the auxiliary coloring layers
24
,
34
, and
44
are not provided in Embodiments 2 through 4, respectively, the constructions of the key top resulting from those Embodiments will be the same.
As occasion demands, modifications may be made as appropriate to provide a new layer to a part of the construction of the above-described pushbutton-switch key top, such as providing a protection layer for protecting the indicator layer
13
,
23
,
33
,
43
or providing a weatherproof resin layer containing an ultraviolet absorbing agent. Also, in the pushbutton-switch key top
11
according to Embodiment 1, for example, a layer for indicating a given design, pattern, color, or the like may be inserted between the adhesive layer
15
and the key top main body
12
separately from the indicator layer
13
. As a result, there may be cases where a step is generated in the key top main body back surface
12
a
when such a layer is formed on the back surface
12
a
of the key top main body
12
. However, the generation of such a step can be alleviated if the transfer is performed using a hot-melt adhesive. Hence, the transferability is not affected.
As a method for transferring the colorant material
18
,
28
,
38
,
48
from the base sheet
19
,
29
,
39
,
49
onto the key top main body
12
,
22
,
32
,
42
, respectively, thermal transfer is performed in addition to the transfer by contact bonding. The conditions for the thermal transfer depend on such various conditions as the materials and thicknesses of the adhesive layer
15
,
25
,
35
,
45
, the key top main body
12
,
22
,
32
,
42
etc., and the air temperature, generally, using a hot-melt adhesive as the adhesive, the base sheet
19
,
29
,
39
,
49
and the key top main body
12
,
22
,
32
,
42
are pressed against each other under the conditions of 150 to 240° C. and 0.3 Mpa for 2 seconds, thereby effecting the transfer.
FIG. 9
is a flowchart comparing the steps of forming an indicator layer in each of the pushbutton switch
10
according to Embodiment 1 and a pushbutton switch that is a conventional product. Now, assume a case where the indicator layer
13
composed of three color materials is provided on the key top back surface and the auxiliary coloring layer
14
of white color is provided on the back surface of the key top main body
12
. In this case, in the conventional product (a), the printing step is performed for each color, and further the drying process needs to be performed for each color. In contrast, in the product of the present invention (b), the colorant layer
18
for indicating a letter, a pattern, or the like can be formed in a single step, and the indicator layer
13
can be provided by performing thermal transfer thereof onto the key top main body
12
through the hot-melt adhesive
15
, thus realizing a significant reduction in the number of steps. The reduction in the number of manufacturing steps will become more pronounced as the number of colors used in a design increases.
(B) “Membrane Switch”
An indicator portion forming method for a membrane switch according to an embodiment of the present invention and a membrane switch having the indication portion will be described with reference to the drawings.
Embodiment 5:
A membrane switch
50
according to an embodiment of the present invention which is shown in
FIG. 10
has a switch portion
51
consisting of a laminate structure obtained by integrating together a base film
5
b
having contact electrodes
51
a
formed in a part of a board circuit (not shown) and a flexible film
51
c
having the contact electrodes
51
a
similarly formed thereon, with a spacer
51
b
being provided therebetween. The switch portion
51
is an area where the force generated by a depressing operation on the membrane switch
50
is applied to execute the switch function, thereby generating an electrical signal. Also, the membrane switch
50
has on a surface of the switch portion
51
an operation sheet
52
which is exposed to the outward appearance of the membrane switch
50
and in which input elements such as letters, symbols, figures etc are indicated. The operation sheet
52
is formed by laminating a translucent film
53
, a first adhesive layer
54
, an indicator layer
55
, and, as occasion demands, an auxiliary coloring layer
56
. Then, the switch portion
51
and the operation sheet
52
are adhered together through a second adhesive layer
57
to be integrated with each other, thereby forming the membrane switch
50
.
The operation sheet
52
as a component of the membrane switch
50
is manufactured as follows. First, a color design image such as a letter, a symbol, or a design is printed on a material sheet
58
from an output device (not shown) that performs batch output of color design data stored in a color printer or the like. Then, a colorant layer
59
containing a colorant such as ink or toner is formed on the base sheet
58
(FIG.
11
A). In this case, a receiving layer (not shown) for allowing the colorant to be borne on the base sheet
58
, a release layer (not shown) for facilitating the transfer of the colorant layer
59
, or the like may be also formed in advance.
Next, an adhesive serving as the first adhesive layer
54
is coated on a surface of the colorant layer
59
(FIG.
11
B). Then, on the base sheet
58
having the respective layers laminated thereon, the translucent film
53
that is transparent or semi-transparent is laminated (FIG.
11
C). The colorant layer
59
is then transferred onto the translucent film
53
from the base sheet
58
by application of pressure, heat, or the like (FIG.
11
D). Thereafter, the base sheet
58
is peeled off. Upon stripping off the base sheet
58
, the transferred colorant layer
59
forms the indicator layer
55
on the translucent film
53
. Thus, the operation sheet
52
having the indicator layer
55
provided on the translucent film
53
is obtained (FIG.
12
A).
To form the membrane switch
50
using this operation sheet
52
, the second adhesive layer
57
is formed on the surface on the indicator layer
55
side of the operation sheet
52
by applying a double-faced tape or an adhesive, and is bonded onto the flexible film
51
c
that constitutes a part of the switch portion
51
of the membrane switch
50
(FIG.
12
B). Thus, the membrane switch
50
in which the operation sheet
52
and the switch portion
51
are integrated together is obtained (FIGS.
12
C and
10
). In the above example, the surface on the indicator layer
55
side is subjected to adhesion so as to ensure that a color design image outputted by the printer can be viewed from the front side (the printing surface side) so that a high-resolution, high-quality image indicative of a letter, a symbol, or a pattern is obtained. Note that, as the switch portion
51
of the membrane switch
50
, it is possible to use a switch portion
51
formed by a commonly used technique such as forming the contact electrodes
51
a
by printing conductive ink on a thin film, making the electrodes oppose each other through the spacer
51
d
, and then adhering the electrodes together.
Colorations that are difficult to express with a color printer, for example, metallic colors such as gold and silver, or colorations such as white and pearl, can be indicated with good reproducibility by separately forming the auxiliary coloring layer
56
that serves to add those colors. That is, for example, a step of laminating the auxiliary coloring layer
56
on the indicator layer
55
by screen-printing or the like is performed between the step shown in FIG.
12
A and that shown in
FIG. 12B
described above (FIG.
13
). Note that this step is unnecessary if there is no need or desire to form the auxiliary coloring layer
56
.
As a method of transferring the colorant material
59
from the base sheet
58
onto the translucent film
53
, thermal transfer is performed in addition to the transfer by contact bonding. The conditions for the thermal transfer depend on such various conditions as the materials and thicknesses of the first adhesive layer
54
, the translucent film
53
etc, and the air temperature: generally, using a hot-melt adhesive as the adhesive, the base sheet
58
and the translucent film
53
are pressed against each other under the conditions of 150 to 240° C. and 0.3 Mpa for 2 seconds, thereby transferring a desired portion of the colorant layer
59
.
In the membrane switch
50
of the present invention, as occasion demands, modifications may be made as appropriate, for example, to provide a new layer such as a weatherproof resin layer containing an ultraviolet absorbing agent to a part of the above-described construction. Also, for example, a layer for indicating a given design, pattern, coloration, etc may be inserted between the first adhesive layer
54
and the translucent layer
53
separately from the indicator layer
53
. There may be cases where a step is generated in the translucent film
53
when such a layer is formed on the translucent film
53
. However, the generation of such a step can be alleviated if the transfer is performed using a hot-melt adhesive and therefore the transfer property is not affected.
Embodiment 6:
A membrane switch
60
according to another embodiment of the present invention is shown in FIG.
14
. While in the membrane switch
50
described in the preceding embodiment the operation sheet
52
is adhered to the flexible film
51
c
of the switch portion
51
that is assembled in advance, in the membrane switch
60
, the operation sheet
62
itself is used as a substitute for the flexible film
51
c
. That is, in this case, using the operation sheet
62
formed in the same manner as the operation sheet
52
manufactured by the method described in the above-described embodiment, the contact electrodes
51
a
are formed in this operation sheet
62
. Then, the step of integrating the operation sheet
62
with the base film
51
b
, which has the contact electrodes
51
a
formed thereon, while sandwiching the spacer
51
d
therebetween is similarly performed as aforementioned. Thus, the membrane switch
60
having the operation sheet
62
as a part of the switch portion
61
is prepared.
In still another embodiment of the present invention, there may be provided a membrane switch (not shown) in which the indicator layer is formed on the flexible film
51
c
by transferring the colorant layer
59
onto the flexible film
51
c
of the switch portion
51
that is assembled in advance.
FIG. 15
is a flowchart comparing the steps of forming an indicator layer in each of the pushbutton switch
50
according to Embodiment 5 and a pushbutton switch that is a conventional product. Now, assume a case where an indicator layer composed of three color materials and an auxiliary coloring layer of white color are provided on a surface of the flexible film. In this case, in the conventional product (a), the printing step is performed for each color, and further the drying step needs to be performed for each color. In contrast, according to the method of manufacturing the membrane switch
50
(b) of the present invention, the colorant layer
59
for indicating a letter, a symbol, a design, or the like can be formed in a single step, and the indicator layer
55
can be provided by performing thermal transfer thereof onto the translucent film
53
through the hot-melt adhesive, thus realizing a significant reduction in the number of steps. Obviously, the reduction in the number of manufacturing steps will become more pronounced as the number of colors used in a design increases.
(2) Materials of Respective Layers
Now, a description will be made of the materials of the respective portions that constitute the pushbutton switch or the membrane switch as an example of a push switch and the materials used for the manufacture thereof
Note that, as for the switch portion
51
of the membrane switch
50
, those materials which are used for the switch portion in a typical membrane switch may be employed. Likewise, materials used for a typical membrane switch may be also employed for portions of the membrane switch
60
other than the operation sheet
62
of the switch portion
61
and for the portions thereof described with reference to other embodiments.
Base Material Sheet
19
,
29
,
39
,
49
and
58
:
The indicator layer
13
,
23
,
33
,
34
,
55
,
65
for indicating letters, symbols, patterns, and the like provided on the front or rear surface of the pushbutton-switch key top
11
,
21
,
31
,
41
and on the rear surface of the operation sheet
52
,
62
is formed of the colorant layer
18
,
28
,
38
,
48
,
59
to be printed on the base sheet
19
,
29
,
39
,
49
,
58
, transferred from an output device that outputs color design data such as a printer. That is, the base sheet
19
,
29
,
39
,
49
,
58
is a sheet that serves as a substrate on which a color design image is formed, and is peeled off after the colorant layer
18
,
28
,
38
,
48
,
59
is transferred thereon. Therefore, it is not a constituent element of the pushbutton-switch key top
11
,
21
,
31
,
41
or the operation sheet
52
,
62
for the membrane switch
50
,
60
. A resin film or paper is used for the base sheet
19
,
29
,
39
,
49
,
58
. Examples of the resin films that can be used include polyethylene terephthalate films, polybutylene terephthalate films, polyurethane films, polyamide films, polypropylene films, polystyrene films, fluoro resin films, ionomer films, polycarbonate films, and polyvinyl chloride films. Further, examples of the papers that can be used include art papers and coated papers. When a paper such as an art paper or a coated paper is used as the base sheet
19
,
29
,
39
,
49
,
58
, ink may penetrate into the base sheet. In such a case, it is difficult to peel off the ink that has penetrated into the base sheet
19
,
29
,
39
,
49
,
58
. Accordingly, a resin film is more preferable than a paper. The kind of the base sheet
19
,
29
,
39
,
49
,
58
to be used is selected from among the above-mentioned resin films and papers depending on the output device that forms the indicator layer
13
,
23
,
33
,
43
,
55
,
65
, such as a printer and on the characteristics of the colorant such as ink or toner. The base sheet
19
,
29
,
39
,
49
,
58
may have any thickness as far as it is within the range that allows printing to be performed by an output device that prints a color design image.
It is desirable that, on the surface of the base sheet
19
,
29
,
39
,
49
,
58
, there is formed: a receiving layer on which a colorant such as ink and toner is easily adhered or carried thereon, according to the output device or the colorant used; or a release layer that serves to prevent the generation of burrs due to transfer and allow the colorant layer
18
,
28
,
38
,
48
,
59
to be easily transferred thereon or subjected to a surface treatment. Alternatively, it is desirable that the base sheet
19
,
29
,
39
,
49
,
58
itself is subjected to a surface treatment. In particular, in the case where the indicator layer
13
,
23
,
33
,
43
,
55
,
65
is formed using an ink jet printer, it is preferable that the receiving layer (or release layer) be provided so as to improve the absorption of ink and make the printed dots be closer to regular circles.
Examples of such a receiving layer (or release layer) include an image bearing layer made of a porous material having a binding phase composed of inorganic fine particles bound by a binder resin. Since the image bearing layer, when ink is printed from a printer, allows the ink to penetrate into the pores, it has excellent ink absorption and also it prevents the flow of ink in the horizontal direction of the base sheet, thereby giving dots that are closer to regular circles, so that the indicator layer
13
,
23
,
33
,
43
,
55
,
65
capable of indicating an image of high resolution can be obtained.
As the inorganic fine particles that form the image bearing layer, there can be used inorganic pigments such as inorganic oxides or hydrates thereof. Specific examples thereof include silica, alumina, alumina hydrate, and silica-alumina composites. An image bearing layer formed with boehmite, which agglomerates of alumina hydrate, or silica-alumina composite sol is preferable since it has a large pore volume and a large mean pore size so that it has excellent in ink absorption and also has excellent transparency, water resistance and glossiness. The mean particle size of the inorganic fine particles is 100 to 1,000 nm, preferably 200 to 800 nm. To increase the transparency of the image bearing layer, it is required to reduce the particle size of the fine particles to a range where substantially no light scattering will occur. In the case where the above-mentioned preferable particle size is used, the image bearing layer becomes opaque, so that even when it is used as a key top or an operation sheet of an illuminated type pushbutton switch, a sufficient light transmittance can be achieved. If the inorganic fine particles have a shape such that they assume a structure in which non-spherical fine particles are oriented to form linear pores, that is, if the image bearing layer has formed therein a large number of longitudinal pores that are open in the direction normal to the plane of the base sheet, then the ink absorption is further enhanced and the shape of dots become closer to regular circles and thus are more preferable.
Further, the binder that binds the inorganic fine particles includes starch and modified products thereof, polyvinyl alcohol and modified products thereof, cellulose derivatives, styrene/butadiene rubber latex, nitrile/butadiene rubber latex, and polyvinylpyrrolidone. Among these, polyvinyl alcohol and modified products thereof are preferable because they have excellent affinity for ink and relatively low glass transition temperature and thus gives satisfactory transferability.
The inorganic fine particles are combined with the binder to form an image bearing layer. The porous structure of the image bearing layer is preferably such that it has a mean pore size of 3 to 25 nm and a pore volume of 0.3 to 2.0 cm
3
/g. In the case where the mean pore size is less than 3 nm or the pore volume is smaller than 0.3 cm
3
/g, the penetration of ink becomes difficult. On the other hand, in the case where the mean pore size exceeds 25 nm or the pore volume exceeds 2.0 cm
3
/g, dots close to regular circles are difficult to form and thus are not preferable.
The porous material having a binding phase composed of inorganic fine particles bound by a binder resin gives advantageous effects not only on improvement of the image quality but also on thermal transfer. That is, when a desired portion of the colorant layer
18
,
28
,
38
,
48
,
59
is to be transferred onto the key top side, if no such image bearing layer is present, the boundary surface between the site to be transferred and the site not to be transferred will not become sharp, thus resulting in poor exfoliation. In contrast, when such an image bearing layer is provided, the boundary surface between the surface to be transferred and the surface not to be transferred is made sharp and in addition the colorant layer
18
,
28
,
38
,
48
,
59
is separated neatly from the base sheet
19
,
29
,
39
,
49
,
58
, so that the problem of a residual color does not occur.
The thickness of the image bearing layer is preferably sufficiently thick to allow penetration of a colorant such as ink printed by a printer, for example, 2 to 50 μm, preferably 7 to 45 μm. If the thickness of the layer is smaller than 7 μm, penetration of the ink becomes insufficient while if it is greater than 45 μm, thermal transfer cannot in some cases be performed neatly.
Indication Layer
13
,
23
,
33
,
43
,
55
,
65
The indicator layer
13
,
23
,
33
,
43
,
55
,
65
is a layer obtained by transferring the colorant layer
18
,
28
,
38
,
48
,
59
, which has a letters, a symbol, a design pattern, or the like formed thereon by printing a color design image on the base sheet
19
,
29
,
39
,
49
,
58
using a printer, onto the key top main body
12
,
22
,
32
,
42
or the translucent film
53
,
63
. The colorant layer
18
,
28
,
38
,
48
,
59
that serves as the basis of the indicator layer
13
,
23
,
33
,
43
,
55
,
65
is formed using an output device that performs batch output of color design images. Atypical example of such an output device is a printer. While a printer may employ various printing systems such as the thermal transfer sublimation system, the ink jet system, or the laser-exposure thermal developing/transfer system, an ink jet printer is preferably used. This is because an ink jet printer allows full-color or high-speed printing to be easily performed, making it possible to obtain an image having excellent resolution and having an almost photograph-like image quality. Further, due to the provision of the above-mentioned image bearing layer, even if an ink for ink jet printing having poor in humidity resistance, weatherability, color developability, scratch resistance etc. is used, the ink is transferred together with the porous material while being infiltrated in the porous material, thereby making it possible to form the indicator layer
13
,
23
,
33
,
43
,
55
,
65
which is excellent in humidity resistance, weatherability, color developability, scratch resistance etc.
When an image is to be directly printed on the basic material sheet
19
,
29
,
39
,
49
,
58
having no receiving layer (or release layer) provided thereon, the colorant material
18
,
28
,
38
,
48
,
59
composed of a colorant such as ink or toner of a printer is transferred to serve as the indicator layer
13
,
23
,
33
,
43
,
55
,
65
. On the other hand, in the case where the image bearing layer provided on the base sheet
19
,
29
,
39
,
49
,
58
serves to absorb the colorant so that the porous material and the colorant are transferred together, the transferred colorant material
18
,
28
,
38
,
48
,
59
inclusive of the porous material serves as the indicator layer
13
,
23
,
33
,
43
,
55
,
65
. In the case where a receiving layer or a release layer is provided other than the above-mentioned image bearing layer, as for the release layer, good resolution and transport property can be attained even if it remains on the base sheet
19
,
29
,
39
,
49
,
58
side without being transferred therefrom. However, as for the receiving layer, it is preferable from the viewpoints of resolution and transferability that the receiving layer does not remain on the base sheet
19
,
29
,
39
,
49
,
58
side.
While the colorant such as ink and toner allowing the expression of a color design image is determined in correspondence with the type of the output device used, ink or toner obtained by dispersing or dissolving pigment or dye in a binder resin is commonly used. For the indication of colors, the CMY system (cyan, magenta, and yellow), the CMYK system (cyan, magenta, yellow, and black), or the RGB system (red, green, and blue) is adopted for the colorant. With such a colorant, full color image representation can be performed by batch output using a color printer, so that a large number of fine letters or numerals, or complex figures, symbols, color patterns etc. can be indicated with sharp clarity in a small area of a key top, thereby forming an indicator portion that is excellent in terms of resolution representing the meticulousness, or preciseness of a drawing or the smoothness of an image.
The indicator layer
13
,
23
,
33
,
43
,
55
,
65
obtained by transferring preferably has such a thickness which allows formation of a sufficient amount of the colorant layer
18
,
28
,
38
,
48
,
59
to enable indication of a color design image and does not hinder the transfer operation. In this example, such a thickness is 1 to 50 μm.
With the indicator layer
13
,
23
,
33
,
43
,
55
,
65
obtained by transferring the colorant layer
18
,
28
,
38
,
48
,
59
that is obtained by printing a color design image using a color printer, for example, an indicator portion having such a design in which, as shown in
FIG. 16
, yellow letters, yellow-orange letters, black letters etc. appear against gradations of yellow and light blue can be formed in a single printing step, thereby making it possible to prepare the pushbutton switch
10
,
20
,
30
,
40
or the membrane switch
50
,
60
having a meticulous design formed thereon.
Adhesive Layer
15
,
25
,
35
,
45
and First Adhesive Layer
54
,
64
For the adhesive layer
15
,
25
,
35
,
45
for binding the indicator layer
13
,
23
,
33
,
43
to the key top main body
12
,
22
,
32
,
43
, or for the first adhesive layer
54
,
64
for binding the indicator layer
54
to the translucent film
53
,
63
, a pressure-sensitive adhesive is used, or an adhesive in the case where the colorant layer
18
,
28
,
38
,
48
,
59
is pressure-transferred, whereas a hot-melt adhesive is preferably used in the case where they are thermally transferred. Examples of the hot-melt adhesive include acrylic-based, polyvinyl chloride-based, polyester-based, and urethane-based hot-melt adhesives. Among these hot-melt adhesive, preferred are those adhesives that have glass transition temperatures of 50 to 100° C. in view of excellent transferability.
The pressure-sensitive adhesive or the adhesive that serves as the adhesive layer
15
,
25
,
35
,
45
as well as the first adhesive layer
54
,
64
is uniformly coated partially or entirely on the key top main body
2
,
22
,
32
,
42
or on the translucent film
53
,
63
, or on the colorant layer
18
,
28
,
38
,
48
,
59
formed on the base sheet
19
,
29
,
39
,
49
,
58
by printing or coating. If a key top of an illuminated type pushbutton switch or an illuminated type membrane switch is to be produced, light must be transmitted and hence the pressure-sensitive adhesive or adhesive is preferably transparent or semi-transparent. The pressure-sensitive adhesive or adhesive may also be colored, increasing the flexibility in design expression. Further, addition of various additives such as ultraviolet absorbents and stabilizers enables improvement of the weatherability to a greater extent. Such an adhesive and the like preferably has satisfactory adhesiveness with respect to the key top main body
12
,
22
,
32
,
43
or the translucent film
53
,
63
serving as adherends. The adhesive layer
15
,
25
,
35
,
45
as well as the first adhesive layer
54
,
64
may have any thickness sufficient for transferring the colorant layer
18
,
28
,
38
,
48
,
59
to the key top main body
12
,
22
,
32
,
42
or the translucent film
53
,
63
, and have generally a thickness in the range of 1 to 30 μm.
Auxiliary Coloring Layer
14
,
24
,
34
,
44
,
56
:
The difficulty of expressing metallic colors like gold or silver, a white color, a pearl color and the like by a color printer is overcome by forming the auxiliary coloring layers
14
,
24
,
34
,
44
and
56
for adding these colors. That is, the auxiliary coloring layer
14
,
23
,
34
,
44
,
56
of white, silver or the like color are provided as laminated on the colorant layer
18
,
28
,
38
,
48
,
59
. It is preferable that at least one ink selected from the group consisting of acrylic-based, polyvinyl chloride-based, urethane-based, ester-based, and epoxy-based inks is used for the auxiliary coloring layer
14
,
24
,
34
,
44
,
56
. The auxiliary coloring layer
14
,
24
,
34
,
44
,
56
is preferably translucent when switches of the illuminated type are to be produced. The thickness of the auxiliary coloring layer
14
,
24
,
34
,
44
,
56
is preferably 1 to 30 μm. If the thickness is less than 1 μm, the effect of adding such colorations as white, silver etc is insufficient. On the other hand, if the thickness is above 30 μm, not only the color adding effect does not increase any more but also the translucency thereof is aggravated. However, in the case where the auxiliary coloring layer
44
is provided on the base sheet
49
side and the auxiliary coloring layer
44
is also transferred to the key top body
43
as shown in Embodiment 4, it is preferred that the auxiliary coloring layer has a smaller thickness from the viewpoint of its transferability.
Key Top Main Body
12
,
22
,
32
,
42
:
The key top main body
12
,
22
,
32
,
42
, which constitutes a part of the pushbutton switch
10
,
20
,
30
,
40
, refers to the portion of the substrate of the key top
11
,
21
,
31
,
41
exclusive of various functional layers such as the indicator layer
13
,
23
,
33
,
43
and the adhesive layer
15
,
25
,
35
,
45
. Mainly a resin is used for the key top main body
12
,
22
,
32
,
42
. The resin is a transparent or semi-transparent resin in Embodiment 1 and may be a resin other than the translucent resin in other embodiments, except for the case where a pushbutton switch of the illuminated type is to be produced. The reasons for the above are as follows. In the case of the pushbutton-switch key top
11
,
21
,
31
,
41
of the illuminated type, light must transmit through the key top main body
12
,
22
,
32
,
42
, so that the resin must be translucent. On the contrary, in Embodiments 2 though 4, the indicator layer
23
,
33
,
43
is formed on the surface of the key top main body
22
,
32
,
43
, so that the key top main body
22
,
32
,
42
needs not be transparent or semi-transparent in order for the indicator portion to be visually recognized.
Examples of the resin that can be used for the key top main body
12
,
22
,
32
,
42
include, for example, various kinds of thermoplastic resins, thermosetting resins, moisture curing resins, and photocuring resins, such as polyester resins, polycarbonate resins, polymethyl methacrylate resins, polyurethane resins, polyamide resins, silicone resins, acrylic resins, and epoxy resins. The key top main body
12
,
22
,
32
,
42
is produced by filling a heat molten resin or a liquid uncured resin in a mold having a desired shape and solidifying it by injection molding, compression molding, transfer molding, rotation molding or the like.
Key Pad
17
,
27
,
37
,
47
:
The pushbutton-switch key top
11
,
21
,
31
,
41
, on which the indicator layer
13
,
23
,
33
,
43
is formed is integrally bonded to the key pad
17
,
27
,
37
,
47
, with rubber-like resilient material, for example, natural rubber, styrene-butadiene rubber, silicone rubber, ethylene/propylene rubber, or a thermoplastic elastomers (hereinafter referred to as “TPE”), for example, styrene-based TPEs, olefin-based TPEs, ester-based TPEs, or urethane-based TPEs to produce the pushbutton switch
10
,
20
,
30
,
40
.
Translucent Films
53
,
63
:
Translucent film
53
,
63
that constitutes the operation sheet
52
,
62
used for the membrane switch
50
,
60
has a function of protecting the indicator layer
55
,
65
. A resin film having light-transmitting property, such as those films made of resins, for example, polyethylene terephthalate films, polybutylene terephthalate films, polyurethane films, polyamide films, polypropylene films, polystyrene films, fluoro resin films, ionomer films, polycarbonate films, and polyvinyl chloride films, can be used for the translucent film. The thickness of the translucent film
53
,
63
is 25 to 200 μm, including situation where they are used in large-scale appliances. However, where a reduction in thickness is desired, the thickness of the translucent film is set to 25 to 100 μm. If the film thickness is smaller than 25 μm, the protection of the indicator layer
55
,
65
is insufficient. On the other hand, a film thickness greater than 200 μm has poor transparency, and is not preferable for a membrane switch that is required to have a small thickness, and in addition the operating feel and the operational accuracy thereof becomes poor so that the switch cannot perform its switch function in a satisfactory manner.
Second Adhesive Layer
57
In the membrane switch
50
, the second adhesive layer
57
for adhering the operation sheet
52
and the switch portion
51
together is a layer having the function of adhering the operation sheet
52
, which is composed of the translucent film
53
, the first adhesive layer
54
, the indicator layer
55
, and, as occasion demands, the auxiliary coloring layer
56
, onto the flexible film
51
c
of the switch portion
51
. In addition to a commonly used adhesive, an adhesive tape or the like may be used for the second adhesive layer
57
.
EXAMPLES
Hereinbelow, the present invention will be described by way of examples and comparative examples. It is to be understood, however, that those examples of the present invention should not be construed restrictively.
Examples 1 through 4 of the invention relate to a pushbutton switch, and more specifically to the manufacture of its key top. Further, Example 5 and Comparative Example 1 relate to a membrane switch.
Example 1
FIG.
1
and FIGS.
2
A through
2
E
On a predetermined base sheet
19
, color design data prepared by using a personal computer is printed by using a predetermined printer, thereby forming a colorant layer
18
on the base sheet
19
. In this case, there are also prepared samples in which a predetermined receiving layer (not shown) is provided on the base sheet
19
. A predetermined translucent hot-melt adhesive layer
15
is uniformly coated by screen printing at a thickness of 5 μm on the back surface
12
a
of a key top main body
12
made of a polycarbonate resin formed by injection molding or on the colorant layer
18
, and is then dried to cure. Thereafter, the key top main body
12
and the base sheet
19
are aligned such that the colorant layer
18
is transferred on the back surface
12
a
side of the key top main body. Then, the key top main body
12
and the base sheet
19
are pressed against each other under the pressure of 0.3 MPa and thermal transfer is effected under application of a predetermined temperature for 2 seconds. Thereafter, the base sheet
19
is peeled off, thereby forming an indicator layer
13
on the back surface
12
a
of the key top main body
12
. Depending on the sample used, a predetermined auxiliary coloring layer
14
is coated at a thickness of 5 μm on the indicator layer
13
. Thus, a pushbutton-switch key top
11
corresponding to each of Samples 1 through 11 is obtained. The materials and manufacturing conditions employed in this case are shown in Tables 1 and 2.
TABLE 1
|
|
Materials and manufacturing conditions employed for respective samples
|
Example 1
|
Sample No.
Sample 1
Sample 2
Sample 3
Sample 4
Sample 5
Sample 6
|
|
Recipient layer
Boehmite/PVA
Xerogel/PVA
Xerogel/PVA
Xerogel/PVA
Xerogel/PVA
Xerogel/PVA
|
Hot-melt adhesive
Acrylic
Acrylic
Acrylic
Acrylic
Urethane
Acrylic
|
layer
|
Auxiliary coloring
None
None
Acrylic
None
Acrylic
Urethane
|
layer
|
Printer type
Ink jet
Ink jet
Ink jet
Ink jet
Thermal transfer
Thermal transfer
|
Base sheet
PET
PET
PET
PET
Polycarbonate
Polycarbonate
|
(thickness)
(100 μm)
(100 μm)
(100 μm)
(100 μm)
(100 μm)
(100 μm)
|
Coating surface for
Back surface of
Colorant layer
Back surface of
Back surface of
Back surface of
Back surface of
|
hot-melt adhesive
key top main body
key top main
key top main
key top main
key top main
|
layer
body
body
body
body
|
Transfer temperature
220° C.
220° C.
220° C.
200° C.
200° C.
200° C.
|
Layer structure
FIG. 1
FIG. 1
FIG. 1
FIG. 1
FIG. 1
FIG. 1
|
|
TABLE 2
|
|
Materials and manufacturing conditions employed for respective samples
|
Example 1
|
Sample No.
Sample 7
Sample 8
Sample 9
Sample 10
Sample 11
|
|
Recipient layer
Polyester/PVA
Polyester/PVA
None
None
None
|
Hot-melt adhesive
Acrylic
Acrylic
Acrylic
Acrylic
Acrylic
|
layer
|
Auxiliary coloring
Acrylic
None
Acrylic
Acrylic
Acrylic
|
layer
|
Printer type
Ink jet
Ink jet
Ink jet
Laser-exposure
Thermal transfer
|
thermal developing/
|
transfer
|
Base sheet
PET
PET
Acryl
PET
PET
|
(thickness)
(100 μm)
(100 μm)
(100 μm)
(100 μm)
(100 μm)
|
Coating surface for
Back surface of key
Colorant layer
Back surface of key
Back surface of key
Back surface of key
|
hot-melt adhesive
top main body
top main body
top main body
top main body
|
layer
|
Transfer temperature
220° C.
220° C.
220° C.
220° C.
220° C.
|
Layer structure
FIG. 1
FIG. 1
FIG. 1
FIG. 1
FIG. 1
|
|
In Tables 1 and 2, used for the PET film serving as the base sheet is LUMIRROR (from Toray Industries. Inc.), used for the polycarbonate film is MAKROFOL (from Bayer Ltd.), and used for the acrylic film is ACRYPLEN HBS001 (from Mitsubishi Rayon Co., Ltd.). As the receiving layer, one of the following is used: an image bearing layer formed of a porous material having a binding phase composed of boehmite that is bound by polyvinyl alcohol; an image bearing layer formed of a porous material obtained by binding xerogel, which is obtained by removing a solvent from silica/alumina composite sol, by polyvinyl alcohol; and a receiving layer formed of polyvinyl alcohol resin/polyester resin (NS-244LX (Takamatsu Oil & Fat Co., Ltd.) formed on the base sheet
19
at a thickness of 25 μm. Further, specific examples of the materials etc indicated in Tables 1 and 2 may be given as follows. That is, SNAP ink (from Jujo Chemical Co., Ltd.) and SG740 ink (from Seiko Advance Ltd.) are used for the “acrylic” hot-melt adhesive and the “urethane” hot-melt adhesive, respectively. Further, STR ink (from Seiko Advance Ltd.) and SG410 ink (from Seiko Advance Ltd.) are used for the “acrylic” auxiliary coloring layer and the “urethane” auxiliary coloring layer, respectively. Further, as for the “ink jet” printer, PM890 (from Seiko Epson Corporation) is used, except that SOLJET SJ-500 (from Roland DG Corporation) is used for Sample 9. For the “thermal transfer” printer and the “laser-exposure thermal developing/transfer” printer, MD5000 (from Alps Electric Co., Ltd.) and Docuprint C 620 (from Fuji Xerox Co., Ltd.) are used, respectively. As for the printer ink, pure ink for use in each type of the printers is used. Note that, with regard to Samples 1, 2, 4, and 8 having no auxiliary coloring layer
14
, for convenience of comparison, it is indicated in Tables 1 and 2 that each of those Samples has a layer structure corresponding to that of FIG.
1
. To be precise, however, the layer structure of each of those Samples corresponds to the structure of
FIG. 3
from which the auxiliary coloring layer
14
is omitted.
Example 2
FIG.
3
and FIGS.
4
A through
4
E
On a predetermined base sheet
29
, color design data prepared by using a personal computer is printed by using a color printer employing a predetermined printing system, thereby forming a colorant layer
28
on the base sheet
29
having a predetermined receiving layer (not shown) provided thereon. Depending on the sample used, a predetermined auxiliary coloring layer
24
is uniformly coated at a thickness of 5 μm on a surface
22
a
of a key top main body
22
made of a polycarbonate resin formed by an injection molder. Then, a predetermined translucent hot-melt adhesive
25
is uniformly coated by screen-printing on the colorant layer
28
or on the surface
22
a
of the key top main body
22
, and is then dried to cure. The key top main body
22
and the base sheet
29
are aligned such that the colorant layer
28
is transferred on the key top
22
side. Then, the key top main body
22
and the base sheet
29
are pressed against each other under the pressure of 0.3 MPa and thermal transfer is effected under application of a predetermined temperature for 2 seconds. Thereafter, the base sheet
29
is peeled off, thus obtaining a pushbutton-switch key top
21
corresponding to each of Samples 12 and 13. The materials and manufacturing conditions employed in this case are shown in Table 3. Note that, with regard to Sample 13 having no auxiliary coloring layer
24
, for convenience of comparison, it is indicated in Table 3 that the layer structure thereof corresponds to that of FIG.
3
. To be precise, however, the layer structure of Sample 13 corresponds to the structure of
FIG. 3
from which the auxiliary coloring layer
24
is omitted.
TABLE 3
|
|
Materials and manufacturing conditions employed for respective samples
|
Example 2
Example 3
Example 4
|
Sample No.
Sample 12
Sample 13
Sample 14
Sample 15
|
|
Recipient layer
Xerogel/PVA
Xerogel/PVA
Xerogel/PVA
Xerogel/PVA
|
Hot-melt adhesive
Acrylic
Urethane
Acrylic
Acrylic
|
layer
|
Auxiliary coloring
Acrylic
None
Acrylic
Acrylic
|
layer
|
Printer type
Ink jet
Laser-exposure thermal
Ink jet
Ink jet
|
developing/transfer
|
Base sheet (thickness)
PET
PET
PET
PET
|
(100 μm)
(100 μm)
(100 μm)
(100 μm)
|
Coating surface for
Colorant layer
Front surface of key top
Colorant layer
Colorant layer
|
hot-melt adhesive
main body
|
layer
|
Transfer temperature
220° C.
200° C.
220° C.
220° C.
|
Layer structure
FIG. 3
FIG. 3
FIG. 5
FIG. 7
|
|
In Table 3, where the same descriptions as those of Tables 1 and 2 are given, the materials described in Table 1 also apply to Table 3.
Example 3
FIG.
5
and FIGS.
6
A through
6
E
Sample 14 is obtained in the same manner as Sample 12 except that the auxiliary coloring layer
24
is provided on the back surface
32
a
of a key top main body
32
, instead of providing it on the front surface
22
a
of the key top main body
22
as in Sample 12 of Example 2.
Example 4
FIG.
7
and FIGS.
8
A through
8
E
Sample 15 is obtained in the same manner as Sample 12 except that, instead of providing the auxiliary coloring layer
24
on the front surface
22
a
of the key top main body
22
as in Sample 12 of Example 2, an auxiliary coloring layer
44
is provided by coating on the front surface of a colorant layer
48
and a hot-melt adhesive
45
is provided by coating on the auxiliary coloring layer
44
provided on the colorant layer
48
.
Example 5
FIG.
10
On a base sheet
58
consisting of a PET film or an acrylic film having a thickness of 100 μm and provided with a predetermined image bearing layer, color design data prepared by using a personal computer is printed by using a predetermined printer, thereby forming a colorant layer
59
on the base sheet
58
. On the colorant layer
59
, a predetermined translucent hot-melt adhesive layer
53
is uniformly coated by screen printing at a thickness of 5 μm and is then dried to cure. Then, alignment is performed so that the colorant layer
59
is transferred onto the translucent film
53
in good conformity with the predetermined translucent layer
53
having a thickness of 50 μm. The base sheet
58
and the translucent film
53
are then pressed against each other under the pressure of 0.3 MPa and thermal transfer is conducted at 200° C. for 2 seconds. Thereafter, the base sheet
58
is peeled off, thereby forming an indicator layer
53
on the front surface of the translucent film
53
. Depending on the sample used, a predetermined auxiliary coloring layer
56
is coated at a thickness of 5 μm on the indicator layer
55
. The operation sheet
52
thus obtained is adhered onto a flexible film
51
of a switch portion
51
using a light-transmissive double-faced tape
55
having a thickness of 150 μm, thereby obtaining a membrane switch corresponding to each of Samples 16 through 22. The materials and manufacturing conditions employed in this case are shown in Tables 4 and 5.
TABLE 4
|
|
Materials and manufacturing conditions employed for respective samples
|
Example 5
|
Sample No.
Sample 16
Sample 17
Sample 18
Sample 19
Sample 20
|
|
Recipient layer
Xerogel/PVA
Boehmite/PVA
Xerogel/PVA
Polyester/PVA
Polyester/PVA
|
(thickness)
(20 μm)
(15 μm)
(20 μm)
(20 μm)
(20 μm)
|
Hot-melt adhesive
Acrylic
Urethane
Acrylic
Acrylic
Acrylic
|
layer
|
Translucent film
Polycarbonate film
Polyester film
Polycarbonate film
Polycarbonate film
Polycarbonate film
|
Auxiliary coloring
None
Acrylic
Acrylic
None
Acrylic
|
layer
|
Printer type
Ink jet
Thermal
Ink jet
Ink jet
Ink jet
|
transfer/
|
sublimation
|
Base sheet
PET
PET
PET
PET
PET
|
Provision of base sheet
None
None
None
None
None
|
as component of
|
membrane switch
|
Viewing direction of
Printing surface
Printing surface
Printing surface
Printing surface
Printing surface
|
indicator layer
side
side
side
side
side
|
Transfer temperature
200° C.
200° C.
200° C.
200° C.
200° C.
|
|
TABLE 5
|
|
Materials and manufacturing conditions employed for respective samples
|
Example 5
Comparative Example 1
|
Sample No.
Sample 21
Sample 22
Sample 23
Sample 24
Sample 25
|
|
Recipient layer
None
None
None
Xerogel/PVA
Xerogel/PVA
|
(thickness)
(20 μm)
(20 μm)
|
Hot-melt adhesive
Acrylic
Acrylic
Acrylic
Acrylic
Acrylic
|
layer
|
Translucent film
Polycarbonate film
Polycarbonate film
Polycarbonate film
Polycarbonate film
Polycarbonate film
|
Auxiliary coloring
Acrylic
Acrylic
Acrylic
None
None
|
layer
|
Printer type
Ink jet
Laser-exposure
Thermal transfer
Ink jet
Ink jet
|
thermal
|
developing/
|
transfer
|
Base sheet
Acryl
PET
PET
PET
PET
|
Provision of base sheet
None
None
None
Provided
Provided
|
as component of
|
membrane switch
|
Viewing direction of
Printing surface
Printing surface
Printing surface
Printing surface
Side opposite to
|
indicator layer
side
side
side
side
printing surface
|
Transfer temperature
200° C.
200° C.
200° C.
Not transferred
Not transferred
|
|
In Tables 4 and 5, used for the PET film serving as the base sheet is LUMIRROR (from Toray Industries. Inc.), and used for the acrylic film is ACRYPLEN HBS001 (from Mitsubishi Rayon Co., Ltd.). As the receiving layer, one of the following is used: an image bearing layer formed of a porous material having a binding phase composed of boehmite that is bound by polyvinyl alcohol; an image bearing layer formed of a porous material obtained by binding xerogel, which is obtained by removing a solvent from silica/alumina composite sol, by polyvinyl alcohol; and a receiving layer formed of polyvinyl alcohol resin/polyester resin (NS-244LX (Takamatsu Oil & Fat Co., Ltd.)) formed on the base sheet
58
. Further, specific examples of the materials etc indicated in Tables 4 and 5 may be given as follows. That is, SNAP ink (from Jujo Chemical Co., Ltd.) and SG740 ink (from Seiko Advance Ltd.) are used for the “acrylic” hot-melt adhesive and the “urethane” hot-melt adhesive, respectively. Further, STR ink (from Seiko Advance Ltd.) is used for the “acrylic” auxiliary coloring layer. Further, as for the “ink jet” printer, PM890 (from Seiko Epson Corporation) is used, except that SOLJET SJ-500 (from Roland DG Corporation) is used for Sample 21. For the “thermal transfer” printer, the “laser-exposure thermal developing/transfer” printer, and the “thermal transfer sublimation” printer, MD5000 (from Alps Electric Co., Ltd.), Docuprint C620 (from Fuji Xerox Co., Ltd.), and CAMEDIA P-400 (from Olympus Optical Co., Ltd.) are used, respectively. As for the printer ink, pure ink for use in each type of the printers is used.
Comparative Example 1
On a base sheet consisting of a PET film having a thickness of 100 μm and provided with a predetermined image bearing layer, color design data prepared by using a personal computer is printed by using a predetermined printer, thereby forming a colorant layer on the base sheet. On the colorant layer, a predetermined translucent hot-melt adhesive is uniformly coated by screen printing at a thickness of 5 μm and then dried to cure. Then, the hot-melt adhesive is melted at 200° C. and adhered onto a predetermined translucent film having a thickness of 50 μm, thereby obtaining an operation sheet formed of the base sheet and the translucent film which are joined together. Thereafter, the operation sheet is adhered onto a flexible film using a light-transmissive double-faced tape. Sample 24 is obtained by joining the base sheet side of the operation sheet to the flexible film, and Sample 25 is obtained by joining the translucent film side of the operation sheet to the flexible film. The materials and manufacturing conditions employed in this case are shown in Table 5.
With respect to Samples 1 through 15 obtained in Examples 1 through 4, evaluations are performed on printing property (resolution), transferability, storage stability, and image quality (color reproducibility). As for the printing property, based on the indication image obtained after the transfer, samples with a very good resolution are marked “A”, samples with a good resolution are marked “B”, and samples with a resolution equivalent to that obtained by conventional screen-printing or the like are marked “C”. With regard to the transferability, samples in which a transfer portion and a non-transfer portion can be sharply peeled off from each other at the boundary therebetween, with no transfer residue remaining on the base sheet, are marked “A”; samples in which the transfer portion and the non-transfer portion can be sharply peeled off from each other but transfer residue remains on the base sheet are marked “B”; and samples in which burrs are generated on the boundary between the transfer portion and the non-transfer portion are marked “C”. Further, the storage stability is evaluated on the basis of a humidity resistance test (45° C., 95% RH, 120 hours), and samples in which the image quality does not change from that of the initial image are marked “A”; samples in which there is even a slight change in the image quality from that of the initial image are marked “B”; and samples in which the image quality is clearly reduced from that of the initial image are marked “C”. As for the image quality (color reproducibility), samples in which full-color representation of a near photograph quality is achieved are marked “A”; samples in which some slight color fading is observed depending on the hue are marked “B”; and samples with inferior image quality are marked “C”. The results are shown in Table 6. In addition to those evaluation items, evaluations are made with respect to the operating feel and operational accuracy. With regard to the operating feel, samples in which a clear depressing sensation is obtained when performing a depressing operation on the switch are marked “A”; samples in which such a sensation is obtained more or less are marked “B”; and samples in which almost no such sensation is obtained are marked “C”. As for the operational accuracy, samples in which on-off switching is effected for a switch with accuracy when performing a depressing operation on the switch are marked “A”; samples in which the switching is not effected in some rare cases are marked “B”; and samples in which the switching is frequently not effected are marked “C”. The results are shown in Table 7.
TABLE 6
|
|
Evaluation results of respective samples
|
Image quality (color
|
Sample No.
Example No.
Printing property
Transferability
Storage stability
reproducibility)
|
|
Sample 1
Example 1
A
A
A
B
|
Sample 2
Example 1
A
A
A
B
|
Sample 3
Example 1
A
A
A
A
|
Sample 4
Example 1
A
A
A
B
|
Sample 5
Example 1
A
A
A
A
|
Sample 6
Example 1
A
A
A
A
|
Sample 7
Example 1
B
B
C
A
|
Sample 8
Example 1
B
B
C
B
|
Sample 9
Example 1
B
C
C
B
|
Sample 10
Example 1
B
C
B
B
|
Sample 11
Example 1
B
C
B
B
|
Sample 12
Example 2
B
A
A
A
|
Sample 13
Example 2
B
A
A
B
|
Sample 14
Example 3
B
A
A
A
|
Sample 15
Example 4
B
A
A
A
|
|
TABLE 7
|
|
Evaluation results of respective samples
|
Sample
Printing
Transfer
Storage
Image quality (color
Operating
Operational
|
No.
Example No.
property
property
stability
reproducibility)
feel
accuracy
|
|
Sample 16
Example 5
A
A
A
B
A
A
|
Sample 17
Example 5
A
A
A
A
A
A
|
Sample 18
Example 5
A
A
A
A
A
A
|
Sample 19
Example 5
B
B
C
B
A
A
|
Sample 20
Example 5
B
B
C
A
A
A
|
Sample 21
Example 5
B
C
C
B
A
A
|
Sample 22
Example 5
B
C
B
B
A
A
|
Sample 23
Example 5
B
C
B
B
A
A
|
Sample 24
Comparative
A
—
A
B
C
C
|
Example 1
|
Sample 25
Comparative
B
—
A
B
C
C
|
Example 1
|
|
Samples 1 through 6 according to Example 1, which are constructed such that a color design image outputted by a printer can be viewed from the front side (the printing surface side), and Samples 16 through 18 according to Example 5 are superior in terms of printing property to Samples 12 through 15, and 22, which are constructed such that the color design image is viewed from the back side (the side opposite to the printing surface). Further, Samples 1 through 6, and 12 through 18 in which an image bearing layer, which is formed of a porous material having a binding phase composed of inorganic particles that are bound by a binder resin, is provided on the base sheet and the image bearing layer is transferred altogether to serve as the indicator layer, are particularly excellent in terms of transferability and storage stability. Further, Samples 3, 5 though 7, 12, 14, 15, 17, 18, and 20 each having the auxiliary coloring layer provided therein are particularly excellent in terms of image quality (color reproducibility). In this case, the evaluation on the image quality is “B” for Samples 9 through 11, and 21 through 23 presumably because no receiving layer is provided therein. Also, Samples 24 and 25 in which the base sheet is used as the operation sheet without being peeled off are clearly inferior in terms of operating feel and operational accuracy.
The pushbutton switch according to the present invention has an indicator layer in which a large number of letters, symbols etc can be indicated and fine, complex picture patterns, color designs etc can be represented, which is excellent in terms of resolution as well as design property.
The membrane switch according to the present invention has an indicator layer in which letters, symbols, complex picture patterns, color designs etc can be indicated with sharp clarity and which is excellent in terms of resolution and design property. The membrane switch provides a good operating feel, making it less prone to depressing operation errors.
Further, the indicator portion forming method for a push switch according to the present invention, in which the indicator layer is formed using an ink jet printer, obviates the need to perform steps such as conventional printing steps regardless of whether a single color image or a multi-color image is to be formed, making it possible to produce push switches inexpensively irrespective of the production quantity thereof without causing the problems of the skill, misregistration, intrusion of foreign matters etc. associated with the use of printing techniques. Further, the push switch according to the present invention, in which the indicator layer having the colorant infiltrated in the image bearing layer is formed, is a push switch having an indicator layer that allows for high image quality and has high water resistance. Further, the push switch according to the present invention is formed by performing thermal transfer of the indicator layer onto the resin serving as a transfer medium with a transparent or semi-transparent hot-melt adhesive, whereby there is no need to perform such post-processing as cutting the printing sheet into a desired shape, thereby allowing easy and high-yield production of the push switch.
Claims
- 1. An indicator portion forming method for a push switch, in which an indicator portion indicating a color design image including a letter, a pattern, and a design is formed on the push switch, the method comprising:forming a colorant layer by printing a color design image on a base sheet by a printer; transferring the colorant layer to a transfer resin through an adhesive, the transfer resin constituting a surface of the push switch; and forming an indicator layer on the transfer resin by peeling off the base sheet and using the colorant layer as the indicator layer.
- 2. An indicator portion forming method for a push switch according to claim 1, wherein the push switch is a pushbutton switch having a key top made of a resin, and the transfer resin is a key top main body of the pushbutton switch.
- 3. An indicator portion forming method for a push switch according to claim 1,wherein the push switch is a membrane switch comprising: an operation sheet which is provided with the indicator layer indicating the color design image including the letter, the pattern, and the design and on which a depressing operation is performed; and a switch portion having contact electrodes provided in opposed positions, the switch portion executing a predetermined switch function when the contact electrodes that are insulated from each other are brought into conduction by the depressing operation on the operation sheet, and wherein the transfer resin is a translucent film constituting a part of the operation sheet.
- 4. An indicator portion forming method for a push switch according to claim 1, wherein the transfer resin is formed of a transparent or semi-transparent resin and the colorant layer is transferred to a back surface of the transfer resin.
- 5. An indicator portion forming method for a push switch according to claim 1, wherein the base sheet has an image bearing layer and the colorant layer is formed by printing the color design image on the image bearing layer by the printer.
- 6. An indicator portion forming method for a push switch according to claim 5, wherein the image bearing layer is formed of a porous material which has a binding phase composed of inorganic particles that are bound by a binder resin and in which a large number of longitudinal slits opening in a direction normal to a plane of the base sheet are formed.
- 7. An indicator portion forming method for a push switch according to claim 1, further comprising forming an auxiliary coloring layer for adding such colorations as metallic colors including gold and silver, or a white color.
- 8. An indicator portion forming method for a push switch according to claim 1, wherein the adhesive is a transparent or semi-transparent hot-melt adhesive and the transfer of the colorant layer is effected by thermal transfer.
- 9. An indicator portion forming method for a push switch according to claim 1, wherein the color design image is printed by using a printer employing an ink jet printing system.
- 10. A push switch which has an indicator portion indicating a color design image including a letter, a pattern, or a design, comprising an indicator layer which is obtained by printing a color design image by a printer through an adhesive layer, on a surface of the push switch.
- 11. A push switch according to claim 10, wherein the push switch is used as a pushbutton switch having a key top made of a resin.
- 12. A push switch according to claim 10, wherein the push switch is used as a membrane switch comprising: an operation sheet which is provided with the indicator layer indicating the color design image including the letter, the pattern, or the design and on which a depressing operation is performed; and a switch portion having contact electrodes provided in opposed positions, the switch portion executing a predetermined switch function when the contact electrodes that are insulated from each other are brought into conduction by the depressing operation on the operation sheet.
- 13. A push switch according to claim 12, wherein the push switch is used as the membrane switch in which the operation sheet constitutes a part of the switch portion and the contact electrodes are formed on the operation sheet.
- 14. A push switch according to claim 10, wherein the surface of the push switch is formed of a translucent resin and the indicator layer is formed on a back surface of the resin.
- 15. A push switch according to claim 10, wherein the indicator layer is formed by transferring a colorant layer to a transfer resin constituting a part of the push switch, the colorant layer being formed by printing the colorant layer on a base sheet having a porous image bearing layer by the printer and impregnating ink into the image bearing member.
- 16. A push switch according to claim 15, wherein the image bearing layer is formed of a porous material which has a binding phase composed of inorganic particles that are bound by a binder resin and in which a large number of longitudinal pores opening in a direction normal to a plane of the base sheet are formed.
- 17. A push switch according to claim 10, further comprising an auxiliary coloring layer for adding such colorations as metallic colors including gold and silver, or a white color.
- 18. A push switch according to claim 10, wherein the adhesive layer is formed of a transparent or semi-transparent hot-melt adhesive.
- 19. A push switch according to claim 10, wherein the indicator layer obtained by transferring the colorant layer printed by an ink jet printer.
- 20. A push switch according to claim 10, wherein each of the layers is translucent so that light exiting from an inner light source can be transmitted therethrough to the exterior for illumination.
Priority Claims (2)
Number |
Date |
Country |
Kind |
2002-160672 |
May 2002 |
JP |
|
2002-160673 |
May 2002 |
JP |
|
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A |
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Shimizu et al. |
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B1 |
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B1 |
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Davidson et al. |
Oct 2002 |
B2 |
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Anderson |
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B2 |
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Shimizu et al. |
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B1 |
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Number |
Date |
Country |
05-090762 |
Dec 1993 |
JP |
2000-231849 |
Aug 2000 |
JP |