CN108076602B

CN108076602B - Flexible electronic device

Info

Publication number: CN108076602B
Application number: CN201710797113.2A
Authority: CN
Inventors: 陈秉宏; 陆隆鸣
Original assignee: INT Tech Co Ltd
Current assignee: INT Tech Co Ltd
Priority date: 2016-11-14
Filing date: 2017-09-06
Publication date: 2020-12-04
Anticipated expiration: 2037-09-06
Also published as: TWM556348U; TWI640816B; CN108073230A; CN207302507U; CN108076602A; TW201818125A; CN207302506U; TWI670697B; TWM555067U; CN207302508U; TWM559510U; TW201839736A

Abstract

The invention discloses a flexible electronic device with good balance weight, comprising: a substrate including at least one folding area dividing the substrate into a plurality of device mounting areas; and a plurality of elements respectively arranged in the plurality of element mounting areas, wherein the gravity centers of the plurality of elements are adjacent to the geometric center of the substrate.

Description

Flexible electronic device

Technical Field

The present disclosure relates to electronic devices, and particularly to a flexible electronic device.

Background

With the development of technology, the flexible panel technology has been applied to electronic devices such as mobile phones and tablet computers. A conventional flexible electronic device generally includes a substrate and a plurality of elements disposed on the substrate. However, since the weights of the components are different, if the components are arbitrarily arranged, the overall weight of the flexible electronic device is biased to one side of the flexible electronic device, which may cause an unbalanced feeling when a user holds the flexible electronic device, and even cause the flexible electronic device to turn over and fall off during use.

Disclosure of Invention

The invention provides a flexible electronic device and a component mounting method thereof, so that the balance weight of the flexible electronic device is improved.

Therefore, the method for mounting components of the flexible electronic device comprises the following steps: providing a substrate, wherein the substrate comprises at least one folding area, and the at least one folding area divides the substrate into a plurality of element mounting areas; and mounting a plurality of components to the plurality of component mounting regions, respectively, such that a center of gravity of the plurality of components is adjacent to a geometric center of the substrate.

In addition, the flexible electronic device includes: a substrate including at least one folding area dividing the substrate into a plurality of device mounting areas; and a plurality of elements respectively arranged in the plurality of element mounting areas, wherein the gravity centers of the plurality of elements are adjacent to the geometric center of the substrate.

The flexible electronic device and the element mounting method thereof can balance the weight distribution of the flexible electronic device, avoid unbalance feeling generated when a user holds the flexible electronic device or overturning and falling in use, and further improve the use convenience of the flexible electronic device.

Drawings

Fig. 1A is a schematic view illustrating an expanded state of a substrate of a flexible electronic device according to the present invention;

fig. 1B is a schematic view of a flexible electronic device according to the present invention with a substrate being folded once;

fig. 1C is a schematic view of a flexible electronic device according to the present invention with a substrate folded for a second time;

FIG. 2A is a top view of the substrate of FIG. 1A;

FIG. 2B is a top view of the substrate of FIG. 1B;

FIG. 2C is a top view of the substrate of FIG. 1C;

FIG. 3 is a schematic view of a configuration of components of a flexible electronic device according to the present invention;

fig. 4 is a schematic circuit module diagram of a flexible electronic device according to the present invention.

Description of reference numerals:

110 substrate

110a, 110b fold region

B_i(B₁、B₂、B₃) Battery pack

C circuit

D. d distance

E_i(E₁、E₂、E₃、E₄) Component

geometric centers of g1, g2 and g3

w1, w2, w3 center of gravity

Z_i(Z₁、Z₂、Z₃、Z₄) Component mounting area

Detailed Description

The specification discloses a flexible electronic device and a method for mounting a plurality of elements contained in the flexible electronic device. By the mounting method, the mounting position of the element in the flexible electronic device can be determined according to the requirement of a designer, and proper weight distribution is obtained, so that the operation of a user is facilitated.

As shown in fig. 1A, the substrate 110 is used for supporting various components to be mounted in the flexible electronic device. For the reader to easily understand, various components carried by the substrate 110 are not labeled in the drawings. The substrate 110 is made of a flexible material, so that it can be folded according to the user's needs. In fig. 1A, the

areas

110a and 110b enclosed by the dashed lines represent the folding areas planned in advance by the designer, respectively. In some embodiments, the width of the folded region is small relative to the size of the substrate 110, and thus can be represented by a single dotted line.

In actual products, the

areas

110a and 110b enclosed by the dotted lines may be visible or invisible to the naked eye, and the dotted lines may be lines close to straight lines, or may be curved lines or a combination of straight lines and curved lines. The

areas

110a and 110b enclosed by the dashed lines may be continuous lines or discontinuous line segments.

In this embodiment, the substrate 110 is designed to be foldable into different embodiments of one fold as shown in FIG. 1B or two folds as shown in FIG. 1C. Fig. 2A-2C are top views corresponding to fig. 1A-1C, respectively, i.e., fig. 2B shows a single fold and fig. 2C shows a double fold.

As shown in FIG. 1A, the mounted components (not shown) may be distributed in four different component mounting areas Z defined by the

dotted areas

110a and 110b as required by the design_i(Z₁,Z₂,Z₃,Z₄) In (1). Each zone Z_iMay be equal to each other or may be unequal to each other. In some embodiments, each zone Z is formed when the substrate 110 is bent through the

dotted areas

110a and 110b_iAnd is not bent with respect to the

dotted line regions

110a and 110 b.

g 1-g 3 represent geometric centers of different shapes in FIGS. 2A-2C, respectively, and the definition of the geometric centers is known to those skilled in the art and can be obtained by geometric calculation, for example, the center of a circle is the geometric center of a circle, and the intersection point of the diagonals of a square or rectangle is the geometric center of the circle.

w 1-w 3 represent the centers of gravity (center of gravity) of the elements in different folded states in FIGS. 2A-2C, respectively. The center of gravity common to the plurality of components can be calculated depending on the weights and the arrangement positions of the plurality of components, and with reference to the folded state of the base plate 110.

It is a feature of the present disclosure that by one approach, the components to be placed can be placed on the substrate 110 and the center of gravity and the geometric center can be aligned with each other, or overlap, or can be held at a distance d as shown in fig. 2A-2C in use in different shapes.

In the use state, the flexible electronic device can provide a preferable weight distribution when the gravity center of the plurality of components is closer to the geometric center of the substrate. That is, the user only needs to hold the geometric center of the substrate to keep the balance of the flexible electronic device, and the flexible electronic device will not be overturned and dropped due to uneven weight distribution during use.

When a plurality of components are disposed, the usage of the flexible electronic device can be considered in advance. For example, the substrate 110 may be in an unfolded state as shown in fig. 1A, a primary folded state as shown in fig. 1B, or a secondary folded state as shown in fig. 1C. If the flexible electronic device is used only in the unfolded state and the first folded state and the second folded state are only required for accommodating, the positions of the elements are designed such that the center of gravity w1 in the unfolded state is close to the geometric center g 1. However, if the flexible electronic device can be operated in the first folding state or the second folding state, the center of gravity w1 is close to the geometric center g1, and the center of gravity w2 is close to the geometric center g2 and the center of gravity w3 is close to the geometric center g 3.

Referring to fig. 2A, the center of gravity w1 of the plurality of elements does not exactly overlap the geometric center g1, but falls at a distance d from the centroid g 1. Because the weight of most components of the flexible electronic device is fixed, and factors such as the installation area, the relative position between the components and the connection relation are considered, and the construction error during installation, it is usually difficult to make the gravity centers of a plurality of components accurately overlap with the approximate center. Generally speaking, when a plurality of components are mounted, if the center of gravity does not exactly overlap the geometric center, and if the center of gravity is only a distance d away from the geometric center, the flexible electronic device can still maintain a balanced state without affecting the convenience of use. In order to maintain the balance, the actual value of the distance D is usually influenced by the shape of the substrate, the total weight of the flexible electronic device, etc., and if the distance D is not greater than 0.1D, preferably not greater than 0.05D, relative to the maximum distance D separating the geometric center g1 from the edge of the substrate.

The plurality of elements may be an image pickup element, a sound amplification element, a battery, a button, and the like. The plurality of elements have substantially no flexibility, so that each element is mainly arranged in one region Z_iWithout overlapping the dashed

areas

110a and 110b for folding. When designing the installation positions of the multiple components, computer simulation and other methods may be used for assistance, and the components with the largest volume or the heaviest weight may be installed in sequence according to the design requirements, which will not be described herein.

In some embodiments, each zone Z_iAre matched, e.g., equal or substantially equal, and are folded in a substantially symmetrical fashion. Therefore, the weight of the plurality of elements can be uniformly distributed in each zone Z_iIn (i.e., dividing the total weight of the plurality of elements by the area Z)_iI.e. in each zone Z_iThe element weight) of (a), whereby the center of gravity w1 of the plurality of elements is brought close to the geometric center g1 of the substrate in the unfolded state. For example, any zone Z_iThe total weight of the elements and another region Z_iThe difference in the total weight of the elements provided therein is preferably not more than 3%. I.e. if zone Z is present₁The total weight of the element set therein is m1, zone Z₂Wherein the total weight of the elements is m2, the following relation should be satisfied:

furthermore, since each zone Z_iFor example, equal or substantially equal, the center of gravity w2, w3 of the plurality of elements remains close to the geometric centers g2, g3 in the one-fold, two-fold embodiments. Alternatively, in some embodiments, zones Z may be further refined_iThe center of gravity of the element arranged therein is close to the region Z_iThe geometric center of (a).

In some embodiments, each zone Z_iAlthough not equal to each other, according to the zones Z, with reference to the above-mentioned method_iBy arranging elements in such an area ratio that each zone Z_iThe ratio of the area of the flexible electronic element to the total weight of the elements arranged in the flexible electronic element is equal, so that the weight distribution of the flexible electronic element is more uniform. Furthermore, each zone Z can be made to be as described above with reference to the above method_iThe center of gravity of the element arranged therein is close to the region Z_iThe geometric center of (a).

In some embodiments, the folding is asymmetric, and the center of gravity w1 of the elements can be close to the geometric center g1 of the substrate, as described above, and the center of gravity w2, w3 of the elements can be close to the geometric centers g2, g3 in the first-folding and second-folding embodiments. Therefore, even if the folding mode is asymmetric folding, the balance weight of the flexible electronic element can be kept balanced, and the unbalanced feeling can be avoided when a user holds the flexible electronic element.

In some embodiments, since the weight of the substrate is not evenly distributed, different zones Z may be considered when mounting the multiple components_iSuch that the total center of gravity of the plurality of components and the substrate is close to the geometric center of the substrate. Similarly, in consideration of the usage situation, the total gravity center of the plurality of elements and the substrate after the first folding and the second folding is still close to the geometric center of the substrate in the first folding and the second folding embodiments. Furthermore, similar to the above method, any region Z can be used_iThe total weight of the components and the substrate and another region Z_iThe sum of the weights of the components and substrates disposed therein are matched, e.g., identical or substantially identical, or differ by no more than 3%.

The plurality of elements can be further divided into positioning elements and non-positioning elements. The positioning element is an element that must be set at a predetermined position on the substrate according to the use requirement or the limitation of hardware setting, such as an image pickup element, a sound amplification element, or a button; the non-positioning element refers to a position that can be arbitrarily changed without affecting the convenience of use or the difficulty of hardware configuration, such as a battery. Therefore, the positioning element can be arranged at a preset position on the substrate, and the non-positioning element can be arranged subsequently, so as to adjust the gravity center position of the plurality of elements.

On the other hand, some components of the flexible electronic device may be separately divided. For example, the battery can be divided into a plurality of battery modules with equal or unequal weight, and the battery modules can be respectively disposed in different areas Z on the substrate 110_iAre connected to each other via a line. In this way, the position of the center of gravity can be further adjusted, and optimal weight balance is realized; meanwhile, the arrangement area of the battery can be enlarged, the thickness of the battery is reduced, and ultra-thinning of the flexible electronic device is facilitated.

In detail, referring to fig. 3, in one embodiment, the battery is divided into a plurality of battery components B_iFour battery packs B shown in FIG. 3₁、B₂、B₃、B₄Actually, battery pack B_iThe total number of the battery modules B can be adjusted according to the requirement_iThe size, amount of electricity, weight, etc. of the above-mentioned components may be equal or different from each other. A plurality of battery components B_i(B₁,B₂,B₃,B₄) And a plurality of elements E other than the battery_i(E₁,E₂,E₃) Region Z disposed on substrate 110_iSuch that its overall center of gravity is located approximately at the geometric center of the substrate 110. Each zone Z_iMay be provided with one or more elements E respectively_iAnd battery pack B_iOr without element E_iOr battery pack B_i. Three elements E shown here_iAnd four battery modules B_iRespectively arranged at different Z_iIn the above formula, the number of the carbon atoms is not limited thereto.

In some embodiments, a plurality of elements E other than the battery can be first arranged_iRegion Z disposed on substrate 110_iIn the region Z, a plurality of battery modules B are arranged on the substrate 110_iSuch that its center of gravity is located approximately at the geometric center of the substrate 110.

In some embodiments, each zone Z_iAre substantially equal, so that each zone Z can be calculated in advance_iThe total weight of the components to be set in the zone Z is distributed and set according to the total weight_iBattery pack B of_iOf any zone Z_iThe total weight of the devices in the same region Z_iThe total weight of the components provided therein is approximately equal, thereby allowing the center of gravity of all components (including the cells) to be located approximately at the geometric center of the substrate 110. For the embodiment of FIG. 3, in Z₁B in the region₁And E₁Total weight of (1) in Z₂B in the region₂And E₂Total weight of (1) in Z₃B in the region₃And E₃Total weight of (1) and in Z₄B in the region₄The total weight of the two components is approximately equal.

In some embodiments, each zone Z_iCenter of gravity of all elements (including battery) in the cell and each region Z_iAlso substantially overlapping. Or as in fig. 2A to 2C, each zone Z_iThe center of gravity of all the elements (including the battery) in the chamber is at a distance d from the geometric center, and each zone Z_iIs defined as D, the distance D is preferably not more than 0.1D, preferably not more than 0.05D. Therefore, the flexible electronic device can have a preferable weight balance in any folding state.

Between the cells of each region, there may be, for example, cell B₁And battery B₂Connected with each other by a circuit C. The circuit may be designed to connect battery B₁And battery B₂Are connected with each other in series or in parallel. The circuit C may comprise several modules as shown in fig. 4.

The circuit C may have a detection module and a switch module. In certain embodiments, each zone Z_iThe power supply of the middle element can be firstly provided with the battery B_iPreferentially supplying cells in different zones, e.g. cell B₁And battery B₂The switch module of the intermediate circuit C disables the battery B in an open state₁And battery B₂There is a current flow between them. At the same time, battery B₁And battery B₂The detection module of the circuit C can detect the battery B₁And battery B₂When the power of any battery is lower than a set value (e.g. lower than 20%), for example, when the battery B is in a state₁When the electric quantity is less than 20%, the switch module is communicated with the battery B in a passage state₁And battery B₂So that battery B₂Can be aligned with the region Z₁The elements in (1) are powered.

In addition, the plurality of elements may further include one or more weights for weight balancing only and substantially without other functions. Because the counterweight does not have other functions, the relative position and the connection relation with other elements are not required to be considered, the weight can be set according to the requirement, even the counterweight can be made of flexible materials, and the setting position has higher degree of freedom, so that the gravity centers of a plurality of elements can be balanced, and the optimal counterweight balance is realized.

The above embodiments are merely illustrative of the principles and technical effects of the present invention, and do not limit the present invention. Modifications and variations of the above-described embodiments may occur to those skilled in the art without departing from the spirit of the invention. The claims of the present invention are to be read as set forth hereinafter.

Claims

1. A component mounting method of a flexible electronic device comprises the following steps:

providing a substrate, wherein the substrate comprises at least one folding area, and the at least one folding area divides the substrate into a plurality of element mounting areas; and

mounting a plurality of components to the plurality of component mounting regions, respectively, such that a center of gravity of the plurality of components is adjacent to a geometric center of the substrate;

the center of gravity of the plurality of components is spaced from the geometric center of the substrate by a distance D, the geometric center of the substrate is spaced from the edge of the substrate by a maximum distance D, and D is less than or equal to 0.1D, wherein the substrate can be folded along the folding area to form a folded configuration, the substrate has a second geometric center in the folded configuration, and the component mounting method of the flexible electronic device further comprises the step of enabling the center of gravity of the plurality of components in the folded configuration to be located at the second geometric center of the substrate.

2. The method as claimed in claim 1, wherein the plurality of components are divided into a positioning component and a non-positioning component; the mounting of the plurality of components to the plurality of component mounting regions respectively includes mounting the positioning component to the plurality of component mounting regions first, and then mounting the non-positioning component to the plurality of component mounting regions.

3. The method as claimed in claim 1, wherein the plurality of components include a battery, the method further comprises separating the battery into a plurality of battery modules, respectively mounting the plurality of battery modules in the plurality of component mounting regions, and connecting the plurality of battery modules with a circuit.

4. The method as claimed in claim 1, wherein the plurality of components include a weight member, and the method comprises mounting the weight member to the plurality of component mounting regions.

5. The method as claimed in claim 1, wherein the areas of the component mounting regions are matched, and the method further comprises matching the total weight of the components disposed in the component mounting regions.

6. The method as claimed in claim 5, further comprising a step of making the difference between the total weight of the components disposed in any one of the component mounting regions and the total weight of the components disposed in another one of the component mounting regions not greater than 3%.

7. The method as claimed in claim 5, further comprising positioning a center of gravity of the component disposed in any one of the component mounting regions adjacent to a geometric center of the component mounting region.

8. A flexible electronic device includes:

a substrate including at least one folding area dividing the substrate into a plurality of device mounting areas; and

a plurality of elements respectively arranged in the plurality of element mounting areas, wherein the gravity centers of the plurality of elements are adjacent to the geometric center of the substrate;

wherein the centers of gravity of the plurality of elements are spaced from the geometric center of the substrate by a distance D, the geometric center of the substrate is spaced from the edge of the substrate by a maximum distance D, and D is ≦ 0.1D;

wherein the areas of the component mounting regions are matched, and the total weight of the components arranged in the component mounting regions is matched;

wherein the center of gravity of a component disposed in any one of the component mounting regions is adjacent to the geometric center of that component mounting region.

9. The flexible electronic device as recited in claim 8, wherein the total weight of components disposed in any one of the component mounting areas differs from the total weight of components disposed in another one of the component mounting areas by no more than 3%.

10. The flexible electronic device as claimed in claim 8, wherein the substrate is foldable along the folding region to form a folded configuration, the substrate has a second geometric center in the folded configuration, and the center of gravity of the plurality of elements in the folded configuration is located at the second geometric center of the substrate.

11. The flexible electronic device according to claim 8, wherein the plurality of components comprise a weight.

12. The flexible electronic device according to claim 8, wherein the plurality of components include a plurality of battery modules and a circuit connected to the plurality of battery modules.

13. The flexible electronic device according to claim 12, wherein the circuit comprises a detection module and a switch module.