TWM492469U - Electronic device - Google Patents

Abstract

An electronic device including a first housing, a touch pad module, and a second housing is provided. The first housing includes an opening. The touch pad module is disposed in the opening. The touch pad module includes a touch pad, a carrying pad, and a composite material structure. The touch pad has a touching region and a keypad region. The carrying pad includes a body and two cantilevers. The body is used for carrying the touch pad. The cantilevers are fixed to the first housing. The touching region is located between the cantilevers and the keypad region. The composite material structure is connected to the carrying pad adjacent to the cantilevers. The second housing is assembled to the first housing, wherein the carrying pad is located between the touch pad and the second housing.

Description

Electronic device

The present invention relates to an electronic device, and more particularly to an electronic device with adjustable feedback feel when pressing a touch panel.

In this era of information explosion, portable electronic devices such as notebook computers, smart phones or tablets have the advantages of being easy to carry, and processing, sending and receiving information, etc., so they are widely accepted by consumers and become the current electronic consumer market. The mainstream.

Taking a notebook computer as an example, it integrates the display screen, the main unit and the input device, so there are other different design considerations for the notebook computer compared to the desktop computer. In terms of controlling the position of the cursor on the display screen, the notebook computer can further utilize the touch panel module and buttons integrated on the casing to achieve similar functions of controlling the movement of the cursor on the display screen through the mouse. Generally, the touch panel of the touch panel module generally corresponds to the switching component setting inside the notebook computer, so that the user can trigger the position inside the notebook by pressing the touchpad located outside the notebook computer. Switching element.

In order to avoid the touch panel being permanently pressed by the user's repeated pressing Shape, the more common practice is to design the rigidity of the touch panel module to a fixed value, so that the mechanical strength of the touch panel module can meet the design specifications. This action causes the touch stroke of the touch panel module to be fixed, and cannot be adjusted according to the user's personal operating habits.

The novel creation provides an electronic device that adjusts the pressing stroke of the touch panel module according to the user's operating habits to provide different feedback feelings of the user.

The electronic device created by the present invention comprises a first casing, a touchpad module and a second casing. The first housing has an opening. The touch panel module is disposed at the opening, and includes a touch panel, a carrier board, and a composite material structure. The touchpad has a touch area and a button area. The carrier plate has a body and two elastic arms. The body is used to carry the touch panel. These spring arms are fixed to the first casing. The touch area is located between the elastic arms and the button area. The composite structure is attached to the carrier plate and adjacent to the spring arms. The second casing is assembled to the first casing, wherein the carrier plate is located between the touchpad and the second casing.

Based on the above, since the electronic device created by the present invention is provided with a composite material structure on the carrier board, and the composite material structure is adjacent to the elastic arm, when the user presses the button area with his finger or an auxiliary tool, the body is generated by the force. It is elastically deformed and has a pressing stroke, wherein the composition of the composite structure affects the magnitude of the pressing stroke so that the user feels a different feedback feel.

The above described features and advantages of the present invention will become more apparent and understood from the following description.

100‧‧‧Electronic devices

110‧‧‧ first case

111‧‧‧ openings

120, 120a‧‧‧ touchpad module

121‧‧‧Touchpad

121a‧‧‧ touch area

121b‧‧‧Keypad area

122‧‧‧Loading board

122a‧‧‧ Ontology

122b‧‧‧Boom arm

123, 123a‧‧‧Composite structure

124, 124a‧‧‧ first material layer

125, 125a‧‧‧Second material layer

126, 126a‧‧‧ third material layer

130‧‧‧Second case

1 is a schematic top plan view of an electronic device according to an embodiment of the present invention.

2 is a partial bottom schematic view of the electronic device of FIG. 1.

3 is a partial cross-sectional view of the electronic device of FIG. 1 taken along line I-I.

4 is another partial cross-sectional view of the electronic device of FIG. 1 taken along line I-I.

1 is a partial top plan view of an electronic device according to an embodiment of the present invention. 2 is a partial bottom schematic view of the electronic device of FIG. 1. 3 is a partial cross-sectional view of the electronic device of FIG. 1 taken along line I-I. Referring to FIG. 1 to FIG. 3 , in the embodiment, the electronic device 100 includes a first casing 110 , a touch panel module 120 , and a second casing 130 . The electronic device 100 is, for example, a notebook computer. However, the present invention does not limit the type of the electronic device 100. Any electronic device using the touch panel module 120 as an input interface can be applied to the present embodiment.

The materials of the first casing 110 and the second casing 130 may be metal, plastic or composite materials, depending on actual design requirements. The first casing 110 has an opening 111, and the touch panel module 120 is disposed at the opening 111. Specifically, the touch panel module 120 includes a touch panel 121 , a carrier 122 , and a composite structure 123 . The touch panel 121 is exposed to the opening 111 for the user to control by operating the touch panel module 100 . Electronic device 100. Generally, the touch panel 121 has a touch area 121a and a button area 121b. When the user slides on the touch area 121a with its finger or auxiliary tool, Controls the cursor movement on the display screen (not shown). When the user presses the button area 121b with the finger or the auxiliary tool, the touch panel 121 can trigger a switching element (not shown) located inside the electronic device 100 to enable the electronic device 100 to perform a specific function.

The carrier plate 122 has a body 122a and two elastic arms 122b connecting the body 122a. The material of the carrier plate 122 is, for example, a metal sheet metal member, and can be integrally formed by stamping. The body 122a can be used to carry the touch panel 121, and the elastic arm 122b can be fixed to the first casing 110. Generally, the elastic arm 122b can be fixed to fix the first casing 110, that is, the carrier plate 122 can be replaced by a screw member (such as a screw) (not shown) passing through the elastic arm 122b. The first casing 110 is locked and thereby carries the touch panel 121. On the other hand, the elastic arm 122b is located, for example, on the side of the body 122a adjacent to the touch area 121a, that is, the touch area 121a is located between the elastic arm 122b and the button area 121b.

The composite structure 123 is connected to the carrier plate 122 and adjacent to the elastic arm 122b. The second casing 130 is assembled to the first casing 10, and the carrier plate 122 is located between the touch panel 121 and the second casing 130. In another aspect, the composite structure 123 is located between the carrier plate 122 and the second housing 130, wherein the composite structure 123 can include a first material layer 124, a second material layer 125, and a third material layer 126 that are stacked, and The composite structure 123 is connected to the carrier plate 122 by, for example, the first material layer 124. Here, the second material layer 125 is located between the first material layer 124 and the third material layer 126, and the first material layer 124, the second material layer 125 and the third material layer 126 are permeable to solder or surface adhesion technology (SMT) ) etc. to firmly bond together. Similarly, the first material The layer 124 and the carrier plate 122 can also be firmly bonded together by welding or surface bonding techniques. As shown in FIG. 3, the composite structure 123 extends from the elastic arm 122b to the body 122a, for example, wherein the first material layer 124, the second material layer 125, and the third material layer 126 are adjacent to the side edges of the elastic arm 122b. .

Specifically, the elastic arm 122b locked to the first casing 110 can be regarded as a fulcrum of the touch panel module 120, and the button area 121b is away from the fulcrum. Therefore, when the user presses the button region 121b with his finger or an auxiliary tool, the body 122a is elastically deformed by the force and has a pressing stroke which is received by the body 122a away from the fulcrum at the body 122a. The amount of displacement change before and after the force is defined. At this time, the elastic arm 122b and the composite material structure 123 are also elastically deformed as the body 122a is actuated, and the elastic potential energy is stored. Therefore, when the user stops applying the force to the button area 121b, the elastic position can be released, and the elastic force is provided to the body 122a through the elastic arm 122b and the composite structure 123, respectively, so that the touch panel 121 is returned to the user. The initial state when the force is pressed against the key area 121b.

For example, under the same force, the larger the pressing stroke, the user will feel the soft feedback feel, and the smaller the pressing stroke, the user will feel the hard feedback feel. To put it another way, under the same pressing stroke, it is necessary to apply a large force to reach the user, which will make the user feel the hard feedback feeling, and if less force is needed to reach the user, the user will feel Soft feedback feel. Different from the above operation principle, the touch panel module 120 can transmit a large feedback force under a large pressing stroke through the configuration relationship of the composite material structure 123, so that the user can feel the harder Feedback feel. Conversely, on a smaller press The feedback force provides a small feedback force, so that the user can feel the soft feedback feel. This will be explained in detail below.

In order to enable the user to feel the hard feedback feeling under a large pressing stroke when the touch panel module 120 is operated, the specific method is to adjust the first material layer 124 in the composite material structure 123, The rigidity of the two material layers 125 and the third material layer 126 is achieved. That is, in the present embodiment, the rigidity of the first material layer 124, the second material layer 125, and the third material layer 126 are different from each other, wherein the rigidity of the third material layer 126 may be greater than the rigidity of the second material layer 125. And the rigidity of the second material layer 125 may be greater than the rigidity of the first material layer 124. In general, the first material layer 124 may be an electrogalvanized steel sheet (SECC) or a cold rolled galvanized steel sheet (SGCC), the second material layer 125 may be a SUS series stainless steel, and the third material layer 126 may be a heat treated layer. Strengthened steel, but the creation of this new type is not limited to this.

As such, when the user presses the key area 121b with his or her finger or an auxiliary tool, it is required to apply a large force to elastically deform the elastic arm 122b and the composite structure 123, and to obtain a large pressing stroke. At this point, the user can feel a hard feedback feel.

In other embodiments, in order to enable the user to feel the soft feedback feel under a small pressing stroke when the touch panel module 120 is operated, the permeable layer of the composite material structure 123 can be adjusted. Composition to achieve. At this time, the rigidity of the second material layer 125 is greater than the rigidity of the first material layer 124, and the rigidity of the first material layer 124 is greater than the rigidity of the third material layer 126 (for example, rubber). Or alternatively, the rigidity of the second material layer 125 is, for example, greater than the rigidity of the third material layer 126, and the third material The rigid design of the layer 126 is, for example, the stiffness of the first material layer 124. In this way, when the user applies a small force to the button area 121b with his finger or an auxiliary tool, the elastic arm 122b and the composite structure 123 can be elastically deformed and a small pressing stroke is obtained. When the user stops applying the force to the button area 121b, the third material layer 126 can rebound immediately, and the elastically deformed elastic arm 122b and the composite structure 123 are quickly returned to the user without pressing the button area. The initial state at 121b. At this time, since the power of the touch panel 121 to the user is small, the user can feel the soft feedback feeling.

4 is another partial cross-sectional view of the electronic device of FIG. 1 taken along line I-I. Referring to FIG. 4, in the embodiment, the composite material structure 123a of the touch panel module 120a is substantially similar to the composite material structure 123 of the touch panel module 120 of the above embodiment, and the main difference is: the first material layer The side edges of the second material layer 125a and the third material layer 126a adjacent to the elastic material 122b are not aligned with each other and are stepped. The material properties and arrangement relationship of the first material layer 124a, the second material layer 125a, and the third material layer 126a may be referred to the above description, and details are not described herein again.

In summary, since the electronic device created by the present invention is provided with a composite material structure on the carrier plate, and the composite material structure is adjacent to the elastic arm, when the user presses the button area with his finger or auxiliary tool, the body is affected by the force. The elastic deformation is generated and has a pressing stroke, wherein the composition of the composite structure affects the magnitude of the pressing stroke, so that the user feels a different feedback feel. Specifically, in the case where the rigidity of the third material layer is greater than the rigidity of the second material layer, and the rigidity of the second material layer is greater than the rigidity of the first material layer, the user needs to apply a large force to press the button. In the key zone, the elastic arm and the composite structure are elastically deformed, and a large pressing stroke is obtained. At this point, the user can feel a hard feedback feel.

In another aspect, the rigidity of the second material layer is greater than the rigidity of the first material layer, and the rigidity of the first material layer is greater than the rigidity of the third material layer (or alternatively, the rigidity of the second material layer is, for example, greater than the third material) The rigidity of the layer, and the rigid design of the third material layer is, for example, the rigidity of the first material. When the user applies less force to press the button area, the elastic arm and the composite structure can be elastically deformed. And get a smaller press stroke. When the user stops applying force to the button area, the third material layer can rebound instantaneously, and the elastically deformed elastic arm and the composite structure can quickly return to the initial state when the user does not apply pressure to the button area. . At this time, since the power of the touch panel to the user is small, the user feels a soft feedback feeling.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the novel creation, and any person skilled in the art can make some changes without departing from the spirit and scope of the novel creation. Retouching, the scope of protection of this new creation is subject to the definition of the scope of the patent application attached.

100‧‧‧Electronic devices

110‧‧‧ first case

120‧‧‧Touchpad module

121‧‧‧Touchpad

121a‧‧‧ touch area

121b‧‧‧Keypad area

122‧‧‧Loading board

122a‧‧‧ Ontology

122b‧‧‧Boom arm

123‧‧‧Composite structure

124‧‧‧First material layer

125‧‧‧Second material layer

126‧‧‧ third material layer

130‧‧‧Second case

Claims (10)

An electronic device includes: a first housing having an opening; a touch panel module disposed on the opening, the touch panel module comprising: a touch panel exposed to the opening and having a touch a control panel and a button area; a carrier board having a body and two elastic arms connected to the body, the body is configured to carry a touch panel, wherein the spring arms are fixed to the first chassis, and the touch An area is located between the elastic arms and the button area; and a composite material structure is connected to the carrier plate and adjacent to the elastic arms; a second casing is assembled to the first casing, wherein the carrier plate is located The touch panel is between the second casing. The electronic device of claim 1, wherein the carrier plate is a metal sheet metal member. The electronic device of claim 1, wherein the composite structure is located between the carrier plate and the second casing. The electronic device of claim 1, wherein the composite material structure comprises a first material layer, a second material layer and a third material layer, and the composite material structure is the first material The layer connects the carrier board. The electronic device of claim 4, wherein the second material layer is located between the first material layer and the third material layer. The electronic device of claim 5, wherein the third material The rigidity of the layer is greater than the rigidity of the second material layer, and the rigidity of the second material layer is greater than the rigidity of the first material layer. The electronic device of claim 5, wherein the second material layer has a rigidity greater than a rigidity of the third material layer, and the third material layer has a rigidity greater than a rigidity of the first material layer. The electronic device of claim 5, wherein the second material layer has a rigidity greater than a rigidity of the first material layer, and the first material layer has a rigidity greater than a rigidity of the third material layer. The electronic device of claim 4, wherein the first material layer, the second material layer and the third material layer are adjacent to each other with the side edges of the elastic arms. The electronic device of claim 4, wherein the first material layer, the second material layer and the third material layer are stepped adjacent to a side edge of the elastic arms.