The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, in the figures, like referenced numerals designate corresponding parts throughout the different views.
In
A touch sensor TS includes a substrate 1, a conductive film 2, insulating films, wiring patterns 8, and a ground pattern 10.
Reference numeral 1 shown in
Since the touch sensor TS can be attached to a curved casing, that is, an attachment flexibility is improved, it is preferable that the substrate 1 is flexible.
The conductive film 2 is formed, for example, on the substrate 1 by screen printing.
As shown in
As shown in
As shown in
In this configuration, eight electrode sections 2a to 2h are surrounded by the grooves 3 extending in the horizontal direction and the vertical direction.
In the embodiment, the electrode sections 2a to 2h are formed in 4 columns by 2 rows.
Among the remaining conductive film 2i outside the electrode sections 2a to 2h, portions of remaining conductive film 2i disposed between the electrode sections 2a to 2h are marked with diagonal lines in
Remaining conductive film 2i not marked with the diagonal lines are described as second remaining conductive film 2i2 outside electrode forming areas of the electrode sections 2a to 2h.
As shown in
As shown in
The dividing grooves 4 and 5 are linearly formed along the horizontal direction (X direction shown in the figure) or the vertical direction (Y direction shown in the figure).
In other words, the dividing grooves 4 are formed parallel to the electrode sections 2a to 2h and the partition grooves 5 are parallel to the ground pattern 10 and the electrode sections 2a to 2h.
The dividing grooves 4 are formed along the centers of the widths between the electrode sections 2a to 2h.
The dividing grooves 5 are formed along the centers of the widths between the electrode sections and the ground pattern.
As shown in
As shown in
The wiring patterns 8 are formed from the insulating films 7 to the electrode sections 2a to 2h and are electrically connected to the electrode sections 2a to 2h.
The wiring patterns 8 extend to connector sections 9 of the touch sensor TS as shown in
As shown in
The ground pattern 10 extends to the connector sections 9.
The wiring patterns 8, the ground pattern 10, and the electrode sections 2a to 2h are covered with an insulating overcoat film 11 formed of the resistor.
As shown in
The electrode sections 2a to 2h are disposed in the sensor sections Sa to Sh, respectively.
For example, the touch sensor Ts shown in
The dividing grooves 4 and 5 shown in
As shown in
The dividing grooves 4 for dividing the first remaining conductive film 2i1 are disposed between the electrode sections 2a to 2h.
The remaining conductive film 2i is minutely partitioned and the remaining conductive film 2i has smaller dimensions by formation of the dividing grooves 4 and 5.
With this configuration, since it is possible to improve the reference sensitivity or suppress the scattering of the reference sensitivity and to achieve the improvement in output variation during the detection by reducing the floating capacitance component, a touch sensor having good operation stability is obtained.
Here, the “reference sensitivity” is determined as a rise of an output to a time before operation of the touch sensor TS (in an initial state when the finger does not touch or approach the sensor sections and the electrostatic capacitance is not changed) and the reference sensitivity is set to a high sensitivity as the rise is sharp.
The reference sensitivity is more specifically described with reference to
As shown in
The pulse signal PL rises from 0V to Vcc at T1 and drops from Vcc to 0V at TS.
At this time, when the pulse signal PL is not output to the all the sensor sections Sa to Sh at the same timing and for example, the pulse signal PL is output to the sensor section Sa, the other sensor sections Sb to Sh have a ground potential.
Now, when the pulse signal PL shown in
At the time when the output OP1 passes Vcc/2 is set to T3, the reference sensitivity (reference value) is determined as T2-T3.
Since the larger the T2-T3, the sharper the rise of the output OP1, a sensitivity is good, while since the smaller the T2-T3, the smoother, the rise of the output OP1, the sensitivity is lowered.
When an electrostatic capacitance C becomes larger, the rise becomes smoother, but in the embodiment described above, it is possible to reduce the electrostatic capacitance C inherent in the sensor sections Sa to Sh from the start by reducing the floating capacitance component, whereby it is possible to set the reference sensitivity to a high sensitivity.
When the finger touches or approaches the touch sensor TS, the electrostatic capacitance is changed between the electrode section 2a corresponding to the sensor section Sa and the finger.
The electrostatic capacitance becomes larger in the change of the electrostatic capacitance. As shown in
A time T4-T3 serves as the output variation and since it is possible to set the reference sensitivity to the high sensitivity, it is possible to increase the output variation in the embodiment.
Although Vcc/2 is used as a threshold value in
In this embodiment, it is possible to reduce the floating capacitance component with respect to each of the sensor sections Sa to Sh by dividing the first remaining conductive film 2i1 and the second remaining conductive film 2i2 outside the electrode sections 2a to 2h by means of the dividing grooves 4 and 5, whereby it is possible to improve the reference sensitivity and to reduce the scattering the reference sensitivity.
In the embodiment, as shown in
The dividing grooves 5, formed on the second remaining conductive film 2i2, are disposed in a direction (in parallel to the electrode sections 2a to 2h and the ground pattern 10) in order to divide the widths between the electrode sections 2a to 2h and the ground pattern 10.
It is preferable that the dividing grooves 4 and 5 are formed along the centers of the widths.
With this configuration, since it is possible to properly reduce the floating capacitance component and to effectively suppress the dimensions of the remaining conductive film 2i opposite each other via the partition grooves 3 in the electrode sections 2a to 2h, it is possible to reduce coupling of the floating capacitance component with the sensor sections Sa to Sh so as to achieve the an improvement in reference sensitivity.
The dividing grooves 4 and 5 are disposed in the directions to divide the widths so as to simply and properly form the dividing grooves 4 and 5 by means of the laser.
The linear dividing grooves 4 and 5 are disposed along the centers of the widths and thus, it is possible to reduce an influence of the floating capacitance component evenly in the sensor sections Sa to Sh so as to more suitably improve the operation stability of the touch sensor TS.
The dividing grooves 4 and 5 are linearly formed so as to form the dividing grooves 4 and 5.
The influence of the electrostatic capacitance occurring between the ground pattern 10 and the second remaining conductive film 2i2 becomes stronger in the vicinity of the ground pattern 10, but since the second remaining conductive film 2i2 are minutely divided by means of the dividing grooves 5 at a position located between the ground pattern 10 and the electrode sections 2a to 2h as described, it is possible to suitably reduce the floating capacitance component generated in the vicinity of the ground pattern 10.
It is possible to properly select whether the touch sensor TS is used with the touch sensor mounted in the casing (an operation surface of the operator's body such as the finger corresponds to the surface of the casing) or the touch sensor is used by exposing the surface of the touch sensor TS as the operation surface depending on a use.
When the touch sensor TS is mounted in the casing, it is possible to arbitrarily determine which surface (the surface of an overcoat film 11 or a rear surface of the substrate 1) of the touch sensor TS shown in
For example, when the touch sensor TS is mounted in a liquid crystal display screen and the touch sensor TS is transparently marked, that is, a transparency is required, it is necessary to form the substrate 1, the insulating films 6 and 7, and the overcoat film 11 by highly transparent materials and to form the conductive film 2 by a transparent conductive film.
The transparent conductive film may be formed of PEDOT (3,4-ethylenedioxythiophene).
Since an optical transmittance of the touch sensor TS can be prescribed in accordance with usage, it is possible to use a semi-transparent insulating film or conductive film.
The wiring patterns 8 are configured to surround the electrode sections 2a to 2h as shown in
One dividing groove 4 and one dividing groove 5 are disposed between the electrode sections 2a to 2h and between the electrode sections 2a to 2b and the ground pattern 10, respectively in the embodiment shown in
In one embodiment, the dividing grooves 4 and 5 are disposed in only one of the remaining conductive film 2i1 and 2i2 in addition to both the first remaining conductive film 2i1 and the second remaining conductive film 2i2. However in another embodiment, it is more preferable that the dividing grooves 4 and 5 are formed in both the first remaining conductive film 2i1 and the second remaining conductive film 2i2.
In one embodiment, the dividing grooves 5 are disposed in only a part of the ground pattern 10 in addition to the entire circumference of the ground pattern 10. The dividing grooves 4 may be disposed in only the first remaining conductive film 2i1 between the electrode sections on one location. However, it is more preferable that the dividing grooves 5 be disposed parallel to the entire circumference (excluding a portion close to the connector section 9) of the ground pattern 10 and the dividing grooves 4 be disposed in the first remaining conductive film 2i1 disposed between the electrode sections as shown in
The ground pattern 10 may be electrically connected onto the second remaining conductive film 2i2.
Planar shapes of the electrode sections 2a to 2h are not limited to rectangular shapes. For example, the planar shapes of the electrode sections 2a to 2h may be circular or elliptical.
In one exemplary embodiment, the wiring patterns 8, the ground pattern 10, the insulating films 6 and 7, and the conductive film are sequentially laminated on the substrate 1 from the bottom, that is, they may be laminated in a reverse order of the order of the embodiment described in
In a manufacturing method of the touch panel TS according to the embodiment of the invention, the conductive film 2 are formed on the entire surface of the substrate 1 by screen printing and then, the partition grooves 3 and the dividing grooves 4 and 5 shown in
As shown in
In the manufacturing method of the touch panel TS according to this embodiment, since it is possible to improve the reference sensitivity and suppress the scattering of the reference sensitivity, and to achieve the improvement in output variation without removing all unnecessary remaining conductive , it is possible to easily manufacture a touch sensor TS having the good operation stability.
The partition grooves 3 and the dividing grooves 4 and 5 are formed on the remaining conductive films 2i by means of the laser. The partition grooves 3 and the dividing grooves 4 and 5 may also be formed, for example, by etching instead of the laser.
However, it is more preferable to use the laser so as to easily form the partition grooves 3 and the dividing grooves 4 and 5.
When the partition grooves 3 are linearly formed on the conductive film 2 in the horizontal direction and in the vertical direction by means of the plurality of lasers and the dividing grooves 4 and 5 are formed parallel to the partition grooves 3 in the directions for dividing the widths of the remaining conductive film 2i positioned between the ground pattern 10 and the electrode sections 2a to 2h and between the electrode sections 2a to 2h by means of the laser as shown in
The data below shows the reference sensitivity and the output variation of the touch sensor according to the Example shown in
In touch sensors described in Comparative Examples 1 to 3, the dividing grooves 4 and 5 shown in
In Example 1 and Comparative Examples 1 to 3, other configurations and test conditions are standardized in consideration of a difference in the presence or absence of the dividing grooves 4 and 5.
A reference value shown in Table 1 corresponds to a value of T2-T3 shown in
The reference value is larger and the rise of an output to a time shown in
Sa to Sh shown in Table 1 represents the sensor sections Sa to Sh shown in
As shown in
In particular, the reference value of the sensor section Sa in Comparative Examples 1 to 3 is 0 or 1 and since the rise of the output is very gentle and the output variation is also 0 or 1, it is difficult to detect the electrostatic capacitance change.
Since two sides of each of the sensor sections Sa, Sd, and Sh are disposed close to the ground pattern 10, electrostatic capacitances inherent in the sensor sections Sa, Sd, and Sh acquiring the floating capacitance components in the vicinity of the ground pattern 10 are significantly higher than those of other sensor sections from the start.
On the other hand, in Example 1, since the reference values in all the sensor sections Sa to Sh can be larger than those in Comparative Examples 1 to 3, it is possible to improve the reference sensitivity and to suppress the scattering of the reference sensitivity.
Since the output variation in the sensor section Sa which has 0 or 1 in Comparative Examples 1 to 3 can be as large as the output variations in other sensor sections and the output variations in the sensor sections Sa to Sh can be evenly large, the operation stability in Example 1 is better than those in Comparative Examples 1 to 3.
Next, a touch sensor in which the second remaining conductive film 2i2 is removed in the Example shown in
The touch sensor according to the Example shown in
In Example 2 and Reference Example 1, other configurations and test conditions are standardized only in consideration of the presence or absence of the second remaining conductive film.
As shown in Table 2, the reference values and the output variations in Example 2 and Reference Example 1 are equal to each other.
Accordingly, it is effective to dispose the dividing grooves without removing all the remaining conductive film.
Number | Date | Country | Kind |
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2006-234413 | Aug 2006 | JP | national |