TWM369504U - Resistance touch panel - Google Patents

Description

M369504 V. New Description: [New Technology Area] This creation is about a touch panel, especially a resistive touch panel. [Prior Art] With the advancement of technology, electronic devices with touch panels such as personal digital assistants (PDAs), mobile phones, and tablet notebook computers are becoming more and more popular. The touch panels on the market can be designed according to their design principles. Divided into several categories, and the most representative touch panel is a resistive touch panel. The principle of the resistive touch panel is to press and touch the surface of the panel with a finger or any object, so that the conductive layer inside the touch panel generates a voltage drop, thereby detecting the touched surface of the touch panel, please refer to the first figure. The first figure is a schematic diagram of components of the resistive touch panel 100 of the prior art. The resistive touch panel 100 includes a first layer 11, a second layer 12, and a control detection module 13. The lower surface of the first layer 11 is provided with two bias lines 111 on both sides of the first direction S1. The two bias lines 111 are electrically connected to the control detecting module 13 by wires 112. The upper surface of the second layer 12 is provided with two bias lines 121 on both sides of the second direction S2. The two bias lines 121 are electrically connected to the control detecting module 13 by wires 122. When the resistive touch panel 100 is in operation, the control detecting module 13 alternately supplies the bias line 111 and the bias line 121 as a bias value, and when the touch panel 100 receives an external force on the first layer 11 of the P1 When the position touches the M369504, the first layer 11 is deformed to touch the second layer 12 at the P2 position. When the control detection module 13 is biased by the bias line 111, the control detection module 13 receives the position voltage signal by the wire 122, and determines the position of the touch point in the first direction S1 by the resistor division method. When the control detection module 13 provides the bias line 121 bias, the control detection module 13 receives the voltage drop through the wire 112, and determines the touch point in the second direction S2 by the resistor voltage division method. position. In other words, the position coordinates of the touch point can be comprehensively known from the position of the touch point in the first direction S1 and the second direction S2. However, since the resistive touch panel 100 of the prior art has only one wire 112 and 122 on the first layer 11 and the second layer 12, if the external force touches the resistive touch panel 100, respectively, the first The layer 11 and the second layer 12 generate touch points PI and P2, and an external force is applied to the resistive touch panel 100 to generate a touch point P3 on the first layer 11 and the second layer 12, respectively. In P4, the wire 112 and the wire 122 cannot simultaneously return the voltage drop generated by the position of the two-touch contact. Therefore, the resistive touch panel 100 of the prior art cannot simultaneously determine a plurality of touch points. In view of the above, the conventional resistive touch panel utilizes the first layer and the second layer to provide a bias between the first direction and the second direction, respectively, and utilizes another layer when one of the plates provides a bias voltage. The position voltage signal generated by the touch point is transmitted, but since the first layer board and the second layer board have only one wire, it is impossible to detect a plurality of touch points at the same time. 4 M369504 [New Content] The technical problems and objectives to be solved by this creative: As mentioned above, the conventional resistive touch panel has the disadvantage of not being able to detect multiple touch points at the same time. Therefore, the main purpose of the present invention is to provide a resistive touch panel having a plurality of conductive blocks to provide a voltage detecting module for detecting voltage values of a plurality of touch points. Measurement. The technical means for solving the problem in the present invention: A resistive touch panel comprises a first panel, a second panel and a voltage detecting module. The touch panel module 5 is disposed on the lower surface of the first panel, wherein the touch panel module has a plurality of independent conductive blocks, and each conductive block includes a sensing line; the second panel has a bias layer mode The group corresponds to the touch panel module, wherein the bias layer module has at least four bias lines, and respectively forms a bias voltage in the first direction and the second direction; and the voltage detecting module respectively senses with the first panel The wires are electrically connected to detect the voltage value of the conductive block. In the preferred embodiment of the present invention, the resistive touch panel further has a control module for providing a bias line bias value, and determining the touch point position of the voltage value detected by the voltage detecting module. Compared with the conventional resistive touch panel, the present invention designs a touch panel M369504 control panel with a plurality of independent conductive blocks on the lower surface of the first panel, and makes each conductive Each of the blocks is connected to a sensing line so that the voltage detecting module detects the voltage value when the area corresponding to the bias layer module is touched. Therefore, the resistive touch surface of the present invention can simultaneously detect The position of at least one touch point is measured to achieve the effect of multi-point input, thereby making the use of the resistive touch panel of the present invention more diversified. The specific embodiments used in the present application will be further illustrated by the following embodiments and drawings. [Embodiment] The present invention relates to a touch panel, and more particularly to a resistive touch panel. The following description of the preferred embodiment is set forth to illustrate the present invention, which is well known to those skilled in the art and is not intended to limit the creation itself. The contents of this preferred embodiment are detailed below. Please refer to the second figure, which is a schematic diagram of the components of the resistive touch panel 200 of the first embodiment. The resistive touch panel 200 includes a first panel 21 , a second panel 22 , and a voltage detecting module 23 . The touch panel module 211 is disposed on the lower surface of the first panel 21, wherein the touch panel module 211 has a plurality of independent conductive blocks 2111, and each of the conductive blocks 2111 includes a sensing line 2112. The first panel 21 can be one of a polyethylene terephthalate (PET) panel or a glass panel, and the touch panel module 211 can be a steel tin oxide. (Indium Tin Oxide; IT0) coated product or a recorded tin oxide (Antimony 6 M369504

Doped Tin Oxide; ΑΤΟ) coated product. The conductive blocks 2lii are arranged according to a sensing array. In the preferred embodiment, the array of sensing arrays may be a matrix or a matrix. The first panel 22 has a partial ink layer module 221 corresponding to the touch panel module 2u. The bias layer module 221 has at least four bias lines 2211 for biasing in the first direction S1 and the second direction, respectively. Wherein the second panel 22 is one of a pET panel or a glass panel, and the bias layer module 221 is a coating. The bias layer module 221 is a uniform planar resistor. Two of the biasing lines 2211 of the laminated layer group 221 are located on opposite sides of the second extending direction S1 of the layer 22, and the remaining: 2211, two biasing lines 2211 are located in the second panel 22, the p-line direction S2 extends on opposite sides. In the present embodiment, the direction S1 and the second direction S2 are orthogonal to each other. The voltage detection module 23 is connected to the auxiliary power of the first panel 21 respectively, and then the electrical conductivity of the conductive block 2111 = the resistance touch panel = the resistive touch panel - further includes the control module 24 The bias line 22n / mold 1 of the second panel 22 provides bias values for the bias lines 2211. Control module: for the voltage detection module, the more electrical connection @亚依电压检测模块 23 & 2U1 voltage value to determine at least - the touch point position of the guide day: for example When the resistive touch panel is fine: the working pull group is connected to the bias line 2 2, the state is reversed, and the _ is interleaved to produce the first direction S1 and the third, so that the partial-universal S2 M369504 bias. When the user simultaneously presses the resistive touch panel 200 and generates the touch point P5 and the touch point P7 on the first panel 21, the first panel 21 is deformed to contact the second panel 22 at the touch point P6. Touching point P8, at this time, the conductive block 2111 corresponding to the touch point P5 and the touch point P7 has a voltage value, and the voltage detecting module 23 receives the voltage values through the sensing line 2112, and The detected voltage value information is transmitted to the control module 24, and the control module 24 synthesizes the voltage value information and the corresponding bias conditions including the bias direction and the bias value, and is applied by using a conventional resistive touch panel. The partial pressure principle determines the position coordinates of the touch point P5 and the touch point P7. Please refer to the third figure, which is a schematic diagram of the components of the resistive touch panel 200' according to the second embodiment of the present invention. Different from the first embodiment of the present invention, the resistive touch panel 200' of the second embodiment of the present invention uses a larger area of the conductive block 211 位置 at a position where the user has less contact, compared to the first implementation. For example, the user's actual use condition can be designed more efficiently, and the number of sensing wires 2112 can be reduced, thereby saving manufacturing costs. In summary, the touch panel module 211 having a plurality of independent conductive blocks 2111, 2111' is disposed on the lower surface of the first panel 21, and each conductive block 2111, 2111' is connected to each other. The sensing line 2112 causes the voltage detecting module 23 to detect the voltage value when the area corresponding to the bias layer module 221 is touched, and further determines, by the control module 24, the position coordinates of the touched contact. Therefore, the resistive touch surface 200, 200' of the present invention can simultaneously detect at least one 8 M369504 touch point positions to achieve the effect of multi-point input, thereby allowing the resistive touch panel 200, 200' of the present creation. It is more diversified. As can be seen from the above-described embodiments of the present invention, the present creation has an industrial use value. However, the above embodiments are merely illustrative of the preferred embodiments of the present invention, and those skilled in the art can make various other modifications and changes as may be described in the above embodiments. However, all of the improvements and variations made in accordance with the present embodiment are still within the scope of the creative spirit and definition of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS The first figure is a schematic diagram of components of a resistive touch panel of the prior art; the second figure is not intended for the resistive touch panel of the first embodiment, and the third The figure is a schematic diagram of components of the resistive touch panel of the second embodiment. [Main component symbol description] Resistive touch panel 10 0 First layer board 11 bias line 111 wire 112 second layer board 12 bias line 121 9 M369504 wire 122 control detection module 13 touch point P P P2 P3, P4 resistive touch panel 200, 200' first panel 21 touch panel module 211 conductive block 2111, 2111' sensing line 2112 second panel 22 bias layer module 221 bias line 2211 voltage detection mode Group 23 Control module 24 Touch points P5, P6, P7, P8 First direction S1 Second direction S2

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Claims (1)

M369504 Six patent application scope: The resistive touch panel comprises: a panel, the lower surface of the touch panel has a plurality of individual cylinders, wherein the electrical block comprises a sensing line; Each of the seven fibers and the touch panel module are respectively opposite to each other; the group has at least four bias lines, and forms a partial ink with the * direction and a second direction; The first panel is a resistive touch panel as described in claim 1, wherein the first panel is A polyethylene terephthalate (PET) panel or a glass panel. 3. The resistive touch panel as described in claim 1 of the scope of the patent application, wherein the touch panel module is made of Indium Tin Oxide (ITO) and a tin oxide (Antimony Doped) At least one of Tin Oxide; ΑΤΟ) is applied to the first panel. 4. The resistive touch panel of claim 1, wherein in the M369504, the second panel is a polyethylene terephthalate (PET) panel or a glass panel. One of them. 5. The resistive touch panel of claim 1, wherein the bias layer module is made of Indium Tin idexide 'ITO and one tin oxide (Antimony Doped) At least one of Tin Oxide; ΑΤΟ) is coated on the second panel. 6. The resistive touch panel of claim 1, wherein the bias layer module is a planar resistor. The resistive touch panel of claim 1, wherein two of the bias wires of the second panel are located on opposite sides of the second panel extending along the first direction, and Among the remaining bias lines, two are located on opposite sides of the second panel extending in the second direction. 8. The electro-acoustic touch panel of claim 1, wherein the first direction and the second direction are orthogonal to each other. 9 · As claimed in the patent application _ 丨 . . , , , , , 立 立 立 立 立 立 立 立 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控 触控The wires are electrically connected to provide 12 M369504 for the bias line bias values. 10. The resistive touch panel of claim 9, wherein the control module is electrically connected to the voltage detecting module and is detected by the voltage detecting module The voltage value of the conductive block determines at least one touch point position. 11. The resistive touch panel of claim 1, wherein the conductive blocks are arranged according to a sensing array. 12. The resistive touch panel of claim 11, wherein the sensing array is arranged in a matrix. 13. The resistive touch panel of claim 11, wherein the sensing array is arranged in a matrix. 13