KR20140100866A - Portable electrnic device - Google Patents

Abstract

A portable electronic device according to an embodiment of the present invention includes first and second device units and at least one hinge assembly configured to pivotably connect the second device unit to the first device unit. The hinge assembly includes a first fixing unit configured to be fixed to the first device unit, a second fixing unit configured to be fixed to the second device unit, a plurality of shaft members configured to be arranged in parallel with one another and to include first and second outer shaft members respectively mounted on the first and second fixing units and a plurality of inner shaft members arranged between the first and second outer shaft members, and a gear unit mounted on the shaft members to connect the plurality of shaft members with one another by gear engagement.

Description

[0001] PORTABLE ELECTRONIC DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable electronic apparatus, and more particularly to a portable electronic apparatus having a display unit pivotable with respect to a main body.

In the case of a portable electronic device such as a laptop computer, which is composed of a main body portion and a display portion, in general, the display portion can be arranged at various angles with respect to the main body portion by being pivotally mounted on the main body portion.

In such a portable electronic device, the display unit is connected to the main body unit through at least one hinge unit to enable pivotal operation. In this case, it is general that the normal hinge portion does not give a feeling that the display portion is smoothly connected to the main body portion, which can be a negative factor in terms of the external appearance design of the portable electronic device.

It is an object of the present invention to provide a hinge assembly capable of giving a feeling of a smooth connection between a first device unit (for example, a main body part) and a second device unit (for example, a display part) and a portable electronic device to which the hinge assembly is applied .

In order to achieve the above object, the present invention provides a semiconductor device comprising: first and second device units; And at least one hinge assembly pivotally connecting the second device unit to the first device unit, the hinge assembly comprising: a first fixed unit fixed to the first device unit; A second fixing unit fixed to the second device unit; A plurality of shaft members arranged in parallel with each other, the first and second outer shaft members being mounted to the first and second fixed units, respectively, and a plurality of inner side members disposed between the first and second outer shaft members, A plurality of shaft members including a shaft member; And a gear unit mounted on the shaft members to connect the plurality of shaft members by gear engagement.

The gear unit may include first and second gear trains arranged in parallel with each other.

The first gear train includes: a first outer gear member coupled to the first outer shaft member; A second outer gear member coupled to the second outer shaft member; And a first group of coupling gear members mounted on the plurality of inner shaft members, wherein the two neighboring shaft members may be comprised of a plurality of coupling gear members connected by a coupling gear member have.

The second gear train may comprise a second group of coupling gear members mounted to the first outer shaft member, the second outer shaft member, and the plurality of inner shaft members.

Wherein the total number of the shaft members is N, the number of coupling gear members of the first group is (N / 2) -1, the number of coupling gear members of the second group is N / 2, May be a natural number that is an even number.

Each coupling gear member includes a first gear part rotatably coupled to any one of two neighboring shaft members; And a second gear part rotatably coupled to the other of the two shaft members.

The first outer gear member, the second outer gear member, the first gear part, and the second gear part may have the form of a spur gear having the same radius.

The hinge assembly may further include a plurality of coupler members, in which two neighboring shaft members are connected by one coupler member.

Each coupler member includes a first coupler part rotatably coupled to either one of two neighboring shaft members; And a second coupler part rotatably coupled to the other of the two shaft members.

Each shaft member may be provided with at least one elastic unit for preventing the second device unit from pivotally moving by an external torque below a threshold value.

The elastic unit may be constituted by a plurality of spring washers which apply an elastic force in the axial direction to the shaft member so as to apply a torque in a direction opposite to the external torque to the shaft member.

The gear unit includes: a first outer gear member mounted on the first outer shaft member;

A second outer gear member mounted on the second outer shaft member; And a plurality of inner gear members fixedly coupled to each of the inner shaft members, wherein the first outer gear member, the second outer gear member, and the plurality of inner gear members can form one gear train have.

The first outer gear member, the second outer gear member, and the plurality of inner gear members may be formed of spur gears having the same radius.

The hinge assembly may further include a plurality of coupler members, in which two neighboring shaft members are connected by one coupler member.

Each coupler member includes a first coupler part rotatably coupled to either one of two neighboring shaft members; And a second coupler part rotatably coupled to the other of the two shaft members.

And a cover unit covering the hinge assembly such that the at least one hinge assembly is obscured from the outside.

The portable electronic device includes: a first hinge assembly; And a second hinge assembly having the same structure as the first hinge assembly and spaced apart from the first hinge assembly in the pivot axis direction, wherein the cover unit includes a plurality of Wherein each cover member may cover one shaft member of the first hinge assembly and the other shaft member of the second hinge assembly corresponding to the one shaft member.

Each cover member may have at least one maximum angular crystal surface that interferes with the movement of the other neighboring cover member when the second device unit is disposed at a maximum angle relative to the first device unit.

In order to achieve the above object, the present invention also provides a hinge assembly for pivotably connecting a first device unit and a second device unit of a portable electronic device, comprising: a first fixing unit fixed to the first device unit; A second fixing unit fixed to the second device unit; A plurality of shaft members arranged in parallel with each other, the first and second outer shaft members being mounted to the first and second fixed units, respectively, and a plurality of inner side members disposed between the first and second outer shaft members, A plurality of shaft members including a shaft member; And a gear unit mounted on the plurality of shaft members to connect the plurality of shaft members by gear engagement.

In order to achieve the above object, the present invention also provides a semiconductor device comprising: first and second device units; And at least one hinge assembly pivotally connecting the second device unit to the first device unit, wherein the hinge assembly includes a plurality of shaft members arranged in parallel with each other, Each of the shaft members is provided with at least one elastic unit for applying a torque to the shaft member in a direction opposite to the external torque, so that the second device unit is prevented from being pivotally moved by external torque.

The elastic unit may be constituted by at least one spring washer which provides an axial elastic force to the shaft member to generate a torque in the opposite direction.

The hinge assembly includes: a first fixing unit fixed to the first device unit; And

Further comprising: a second fixed unit fixed to the second device unit, wherein the plurality of shaft members include: a first outer shaft member mounted to the first fixed unit; A second outer shaft member mounted on the second fixed unit; And a plurality of inner shaft members disposed between the first and second outer shaft members.

The hinge assembly may further include a gear unit mounted to the shaft members to connect the plurality of shaft members by gear engagement.

In order to achieve the above object, the present invention also provides a hinge assembly for pivotably connecting a first device unit and a second device unit of a portable electronic device, comprising a plurality of shaft members arranged in parallel with each other, Wherein each shaft member is provided with a hinge assembly mounted with at least one resilient unit for applying a torque to the shaft member in a direction opposite to the external torque so as to prevent pivotal movement of the second device unit by an external torque less than the value do.

In order to achieve the above object, the present invention also provides a semiconductor device comprising: first and second device units; First and second hinge assemblies of the same construction pivotally connecting the second device unit to the first device unit and spaced apart in the pivot axis direction; And a cover unit covering the first and second hinge assemblies, wherein each hinge assembly includes a plurality of shaft members arranged in parallel with each other, and the cover unit includes a portion of the plurality of shaft members Wherein each of the cover members includes a first shaft member of the first hinge assembly and a second shaft member of the second hinge assembly corresponding to the one shaft member, The present invention provides a portable electronic device.

Each cover member may have at least one maximum angular crystal surface that interferes with the movement of the other neighboring cover member when the second device unit is disposed at a maximum angle relative to the first device unit.

1 is a perspective view showing a portable electronic device according to a first embodiment of the present invention in a folded state.
2 is a side view of the electronic apparatus shown in Fig.
3 is a perspective view of the electronic apparatus shown in Fig. 1 in an unfolded state.
4 is a side view of the electronic device shown in Fig.
Fig. 5 is a perspective view of the electronic apparatus shown in Fig. 1, with the cover unit omitted. Fig.
Figure 6 is a perspective view of the hinge assembly shown in Figure 5;
7A is an exploded perspective view of the hinge assembly shown in FIG.
7B is a perspective view illustrating some of the components of the hinge assembly shown in FIG. 7A.
8A is a side view showing one cover member and a pair of cover mounting members coupled thereto.
FIG. 8B is a cross-sectional view taken along the line III-III of FIG. 8A. FIG.
9A is a side view of the hinge assembly shown in FIG.
Fig. 9B is a cross-sectional view taken along line I-I of Fig. 6. Fig.
FIG. 9C is a cross-sectional view taken along line II-II of FIG. 6. FIG.
Fig. 10A is a view corresponding to Fig. 9A, and is a side view showing a state in which the second device unit is unfolded.
Fig. 10B is a cross-sectional view showing a state in which the second device unit is unfolded, corresponding to Fig. 9B.
Fig. 10C is a cross-sectional view corresponding to Fig. 9C showing a state in which the second device unit is unfolded.
11 is a perspective view showing the portable electronic device according to the second embodiment of the present invention in a completely opened state.
12 is a side view of the electronic apparatus shown in Fig.
13 is a perspective view showing the electronic apparatus shown in Fig. 11 in a less unfolded state.
14 is a side view of the electronic apparatus shown in Fig.
Fig. 15 is a perspective view of the electronic apparatus shown in Fig. 11, with the cover unit omitted.
Figure 16 is a perspective view of the hinge assembly shown in Figure 15;
17A is an exploded perspective view of the hinge assembly shown in FIG.
17B is a perspective view showing a part of the parts of the hinge assembly shown in FIG.
18A is a side view showing one cover member and a pair of cover mounting members coupled thereto.
18B is a cross-sectional view taken along the line V-V in FIG. 18A.
FIG. 19A is a side view of the hinge assembly shown in FIG. 16, showing the hinge assembly as fully deployed.
Fig. 19B is a cross-sectional view taken along the line VI-VI of Fig. 16, showing the hinge assembly being fully opened.
FIG. 20A is a view corresponding to FIG. 19A, showing the hinge assembly when it is unfolded. FIG.
Fig. 20B is a view corresponding to Fig. 19B showing the hinge assembly when it is unfolded. Fig.

1 to 4 show a portable electronic device 1 according to a first embodiment of the present invention, in which the portable electronic device 1 is illustrated as a laptop computer. However, the present invention is equally applicable to other types of electronic apparatuses having at least one device unit pivotally mounted on the apparatus body so as to enable folding and unfolding operations.

The portable electronic device (1) includes a first device unit (10) and a second device unit (20).

The first device unit 10 is a part constituting the main body of the portable electronic device 1 and has a plurality of input keys 13 and a touch pad 14 on its upper surface. A control unit (not shown) for controlling the operation of the portable electronic device 1 is embedded in the first device unit 10 in the form of a circuit board.

The first device unit 10 includes a base portion 11 placed at a place such as a table or a knee and a hinge mounting portion 12 vertically protruding from one end of the base portion 11. The hinge mounting portion 12 is coupled to one side of a hinge assembly described later.

The second device unit 20 is a part constituting the display unit of the portable electronic device 1 and has a display screen 23 on its inner side. In order to provide the display screen 23, the second device unit 20 may be provided with a display panel such as an LCD panel and an OLED panel.

The second device unit 20 is pivotable about the pivot axis P1 (see Fig. 3) relative to the first device unit 10. [ 4, the second device unit 20 is pivotable in the direction (A direction) in which the first device unit 10 is folded, and is also pivotable in the direction in which the first device unit 10 is extended from the first device unit 10. [ B direction).

Thus, the second device unit 20 can be arranged at various angles with respect to the first device unit 10. [ As shown in Figures 1 and 2, the second device unit 20 can be fully folded into the first device unit 10, at which the angle between the two units 10, 20 is 0 [deg.]. 3 and 4, the second device unit 20 may be disposed in an extended state from the first device unit 20 so that the display screen 23 is exposed to the outside. 3 and 4 show the second device unit 20 fully opened, wherein the angle between the second device unit 20 and the first device unit 10 is approximately 120 [deg.]. In alternative embodiments, the maximum angle may be set to a different value (e.g., 130 degrees, 150 degrees, 180 degrees, etc.).

The portable electronic device 1 also includes a cover unit 30 disposed between the hinge mounting portion 12 of the first device unit 10 and the lower end portion 21 of the second device unit 20. [

The cover unit 30 is for covering the hinge assemblies 100A and 100B described later. The cover unit 30 includes a total of six cover members 31-36 extending a distance corresponding to the width of the second device unit 20 along the pivot axis P1. The second cover member 32, the third cover member 33, the fourth cover member 33, and the third cover member 33 in the order of the first device unit 10 close to the hinge mounting portion 12, Member 34, fifth cover member 35, and sixth cover member 36, respectively.

Referring to Fig. 2, each cover member 31-36 has a maximum angular crystal face. That is, the first cover member 31 has the maximum angular crystal face 31a, the second cover member 32 has the maximum angular crystal faces 32a and 32b, and the third cover member 33 has the maximum angular crystal faces And the fourth cover member 34 has the maximum angular crystal faces 34a and 34b and the fifth cover member 35 has the maximum angular crystal faces 35a and 35b, 36 have the maximum crystal face 36a.

3 and 4, when the second device unit 20 is disposed at 120 degrees (the maximum setting angle) with respect to the first device unit 10, each of the maximum angular crystal faces has a maximum And contact with each crystal plane to interfere with movement of the cover member. For example, the maximum angular crystal face 31a of the first cover member 31 contacts the maximum angular crystal face 32b of the neighboring second cover member 32, and the maximum angular crystal face 33a contact the maximum angular crystal faces 34b of the neighboring fourth cover member 34. [ The additional pivoting of the second device unit 20 in the direction B is restricted by mutual contacts between these maximum crystal faces so that the maximum angle between the second device unit 20 and the first device unit 10 is approximately 120 < / RTI >

5 is a perspective view of the above-described portable electronic device 1 shown with the cover unit 30 omitted. Referring to this figure, the portable electronic device 1 includes two hinge assemblies 100A and 100B spaced from each other in the direction of the pivot axis P1. These hinge assemblies 100A and 100B serve to pivotably connect the second device unit 20 to the first device unit 10. [

Although the portable electronic device 1 is illustrated as employing two hinge assemblies 100A and 100B, the portable electronic device 1 may alternatively employ only one hinge assembly or three or more hinge assemblies have.

Here, the hinge assembly 100A and the hinge assembly 100B have exactly the same structure. Accordingly, the hinge assembly 100A will be described below as an example, and the structure of the hinge assembly 100B will be easily understood from the description of the hinge assembly 100A.

6A is a perspective view of the hinge assembly 100A, FIG. 7A is an exploded perspective view of the hinge assembly 100A of FIG. 6, and FIG. 7B is a perspective view of the parts of the hinge assembly shown in FIG. 7A.

6, 7A and 7B, the hinge assembly 100A includes first and second fixed units 110 and 120, a plurality of shaft members 130, 140, 150, 160, 170 and 180, a gear unit 200, 330, 340, 350, 360, 370 and a plurality of elastic units 430A, 430B, ..., 480A, 480B.

The first fixed unit 110 is a component for fixing the hinge assembly 100A to the first device unit 10. [ The first fixed unit 110 is fixed to the hinge mount 12 (see Fig. 2) of the first device unit 10 by screw members (not shown). Accordingly, the first fixing unit 110 has a plurality of screw through holes 111, 112, and 113 formed therein.

The first fixing unit 110 is provided with a first cover mounting member 131 and the first cover member 31 described above is mounted on the first cover mounting member 131.

The second fixing unit 120 is a part for fixing the hinge assembly 100A to the second device unit 20. [ The second fixing unit 120 is fixed to the lower end portion 21 of the second device unit 20 by screw members (not shown). Accordingly, the second fixing unit 120 has a plurality of screw through holes 121, 122, and 123 formed therein.

The second fixing unit 120 is provided with a sixth cover mounting member 181 and the sixth cover member 36 described above is mounted on the sixth cover mounting member 181.

The plurality of shaft members 130,140,150,160,170,180 comprise first and second outer shaft members 130,180 disposed outermost and four inner shaft members 140,150,160,170 disposed between the outer shaft members 130,180. do.

The plurality of shaft members 130,140,150,160,170,180 are arranged parallel to the pivot axis P1 of the second device unit 20 (see Fig. 3). The gap between any two adjacent shaft members of the plurality of shaft members 130, 140, 150, 160, 170, 180 is maintained constant.

The first outer shaft member 130 is mounted on the first cover mounting member 131 provided in the first fixing unit 110 and the second outer shaft member 180 is mounted on the second fixing unit 120 And is mounted on the second cover mounting member 181. The first and second cover mounting members 131 and 181 are formed with through holes 131a and 181a having a non-circular cross section in which the first and second shaft members 130 and 180 are inserted. The first and second shaft members 130 and 180 are fixed to the first and second cover mounting members 131 and 181 because the through holes 131a and 181a have a non-circular cross section. Since the first and second cover mounting members 131 and 181 are components fixed to the first and second device units 10 and 20, the first and second outer shaft members 130 and 180 are fixed to the first and second device units 10 and 20, (10,20), respectively, without relative movement.

The second to fifth cover mounting members 141, 151, 161, and 171 are coupled to the four inner shaft members 140, 150, 160, and 170, respectively. The cover mounting members 141, 151, 161, and 171 are each formed with through holes 141a, 151a, 161a, and 171a having non-circular cross sections into which the corresponding inner shaft members 140, 150, 160, and 170 are inserted.

The shaft members 130, 140, 150, 160, 170, and 180 are formed with spacing portions 132, 142, 152, 162, 172, and 182 protruding in the circumferential direction. The first outer shaft member 130 is formed with a gear engagement portion 133 having a non-circular cross section and disposed adjacent to the spacing portion 132. The second outer shaft member 180 is provided with a spacer portion 182 A gear engagement portion 183 of a non-circular cross-section disposed adjacent thereto is formed.

The gear unit 200 is mounted on the shaft members 130, 140, 150, 160, 170 and 180 so that the shaft members 130, 140, 150, 160, 170 and 180 are connected by gear engagement. The gear unit 200 includes a total of seven gear members. More specifically, the gear unit 200 includes first and second outer gear members 210 and 220 and five coupling gear members 230, 240, 250, 260 and 270.

When the user applies a torque for pivoting to the second device unit 20, the gear unit 200 transmits a portion of its torque to each shaft member 130-180, The pivotal movement of the second device unit 20 is carried out.

The first outer gear member 210 is provided with a spur gear having a plurality of gear teeth 211 formed thereon. The first outer gear member 210 is formed with a through hole 212 that is passed by the first outer shaft member 130. The first outer gear member 210 has a shaft engaging portion 215 coupled to the gear engaging portion 133 of the first outer shaft member 130 described above. The shaft coupling portion 215 is formed with a through hole (not shown) having a shape corresponding to the shape of the gear coupling portion 133. It can be seen that the first outer gear member 210 is fixed to the first outer shaft member 130 since the gear engagement portion 133 has a non-circular cross-section.

The second outer gear member 220 is provided as a spur gear having a plurality of gear teeth 221 formed thereon. The second outer gear member 220 is formed with a through hole 222 that is passed by the second outer shaft member 180. The second outer gear member 220 has a shaft engaging portion 225 coupled to the gear engaging portion 183 of the second outer shaft member 180 described above. The shaft coupling portion 225 is formed with a through hole (not shown) having a shape corresponding to the shape of the gear coupling portion 183. It can be seen that the second outer gear member 220 is fixed to the second outer shaft member 180 since the gear engagement portion 183 has a non-circular cross-section.

The first group of coupling gear members 230 and 240, which form part of the five coupling gear members 230, 240, 250, 260 and 270, together with the first and second outer gear members 210 and 220, . The two coupling gear members in the first group are referred to as first coupling gear member 230 and second coupling gear member 240, respectively. In other words, the first gear train 201 includes a first outer gear member 210, a first coupling gear member 230, a second coupling gear member 240, and a second outer gear member 240, (220), and these four gear members (210, 230, 240, 220) are engaged with each other.

Meanwhile, the second group of coupling gear members 250, 260 and 270 constituting the remaining part of the five coupling gear members 230, 240, 250, 260 and 270 may include a second gear train 202 disposed in parallel with the first gear train 201 . The three coupling gear members in the second group are referred to as a third coupling gear member 250, a fourth coupling gear member 260, and a fifth coupling gear member 270, respectively. In other words, the second gear train 202 is composed of a third coupling gear member 250, a fourth coupling gear member 260, and a fifth coupling gear member 270 which are sequentially disposed, The three gear members 250, 260 and 270 are engaged with each other.

The first coupling gear member 230 includes first and second gear parts 231 and 235 integrally formed. The first gear portion 231 is rotatably coupled to the first inner shaft member 140 by having a through hole 232 having a circular cross section. The second gear portion 235 is also rotatably coupled to the second inner shaft member 150 by having a through hole 236 having a circular cross section. The gap between the first inner shaft member 140 inserted into the first gear part 231 and the second inner shaft member 150 inserted into the second gear part 232 is maintained constant.

The first and second gear parts 231 and 235 are configured in the form of a spur gear having the same radius. The radii of the first and second gear parts are the same as the radii of the first and second outer gear members 210 and 220. The first coupling gear member 230 includes a first outer gear member 210 and a second coupling gear member 240 disposed adjacent to each other via the first gear portion 231 and the second gear portion 235, Respectively.

The second to fifth coupling gear members 240, 250, 260, 270 each have the same shape as that of the first coupling gear member 230 described above. Therefore, the second to fifth coupling gear members 240, 250, 260 and 270 will be briefly described as follows.

The second coupling gear member 240 includes first and second gear parts 241 and 245 which are integrally formed and the first gear part 241 and the second gear part 245 are provided with through holes 242 And a through hole 246, respectively. The gap between the third inner shaft member 160 and the fourth inner shaft member 170 is kept constant by the second coupling gear member 240. [ The second coupling gear member 240 is connected to the first coupling gear member 230 and the second outer gear member 220 disposed adjacent to each other via the first gear portion 241 and the second gear portion 245, Engage gears respectively.

The third coupling gear member 250 includes first and second gear parts 251 and 255 integrally formed and the first gear part 251 and the second gear part 255 are provided with through holes 252 And a through-hole 256, respectively. The gap between the first outer shaft member 130 and the first inner shaft member 140 is kept constant by the third coupling gear member 250. [ The third coupling gear member 250 engages with the fourth coupling gear member 260 disposed adjacent thereto through the second gear part 255.

The fourth coupling gear member 260 includes integrally formed first and second gear parts 261 and 265. The first gear part 261 and the second gear part 265 are provided with through holes 262 having a circular cross section And a through hole 266, respectively. The gap between the second inner shaft member 150 and the third inner shaft member 160 is kept constant by the fourth coupling gear member 260. [ The fourth coupling gear member 260 is connected to the third coupling gear member 250 and the fifth coupling gear member 270 disposed adjacent to each other through the first gear portion 261 and the second gear portion 265, Respectively.

The fifth coupling gear member 270 includes first and second gear parts 271 and 275 integrally formed and the first gear part 271 and the second gear part 275 are provided with through holes 272 And a through-hole 276 are formed. The gap between the fourth inner shaft member 170 and the second outer shaft member 180 is kept constant by the fifth coupling gear member 270. The fifth coupling gear member 270 engages with the fourth coupling gear member 260 disposed adjacent thereto through the first gear part 271.

In this embodiment, a total of six shaft members 130-180 are provided, the first gear train 201 includes a first group of two coupling gear members 230, 240, and the second gear train 202 Includes a third group of three coupling gear members (250, 260, 270). If the number of shaft members is selected differently, the number of coupling gear members of the first group and the number of coupling gear members of the second group must also be changed. However, the number of shaft members should be even (e.g., 8, 10, 12, etc.).

Here, the relationship between the number of shaft members, the number of coupling gear members of the first group, and the number of coupling gear members of the second group can be defined as follows. The number of coupling gear members of the first group belonging to the first gear train is (N / 2) -1 when the number of the plurality of shaft members is N (N is a natural number which is an even number) The number of coupling gear members in the second group is N / 2. For example, when 10 shaft members are applied, four (= 10 / 2-1) coupling gear members are arranged in the first gear train and five (= 10/2) couples are arranged in the second gear train. A ring gear member is disposed.

The plurality of coupler members 330, 340, 350, 360, and 370 are for keeping the gap between any two neighboring shaft members constant. The first coupler member 330, the second coupler member 340, the third coupler member 350, the fourth coupler member 360, and the fifth coupler member 370 are referred to as the first coupler member 330, the second coupler member 340, the third coupler member 350,

Each of the coupler members 330, 340, 350, 360, and 370 includes a first coupler part rotatably coupled to one of the shaft members and a second coupler part rotatably coupled to the other one of the shaft members adjacent to the shaft member, The first and second coupler parts are integrally formed. Each of the coupler members 330, 340, 350, 360, and 370 will be described in more detail as follows.

The first coupler member 330 is composed of a first coupler part 331 having a through hole 332 of a circular section and a second coupler part 335 having a through hole 336 of a circular section. The first coupler part 331 is rotatably coupled to the first inner shaft member 140 through the through hole 332 and the second coupler part 335 is coupled to the first inner shaft member 340 through the through hole 336. [ Is rotatably coupled to a second inner shaft member (150) disposed adjacent to the first inner shaft member (140). Thus, the distance between the first inner shaft member 140 and the second inner shaft member 150 is kept constant by the first coupler member 330. [

The second coupler member 340 is comprised of a first coupler part 341 having a circular cross section through hole 342 and a second coupler part 345 having a circular cross section through hole 346. The gap between the third inner shaft member 160 and the fourth inner shaft member 170 is kept constant by the second coupler member 340. [

The third coupler member 350 is composed of a first coupler part 351 having a through hole 352 having a circular section and a second coupler part 355 having a through hole 356 having a circular section. The gap between the first outer shaft member 130 and the first inner shaft member 140 is kept constant by the third coupler member 350.

The fourth coupler member 360 is composed of a first coupler part 361 having a through hole 362 having a circular section and a second coupler part 365 having a through hole 366 having a circular section. The distance between the second inner shaft member 150 and the third inner shaft member 160 is kept constant by the fourth coupler member 360. [

The fifth coupler member 370 is composed of a first coupler part 371 having a circular-section through-hole 372 and a second coupler part 375 having a circular-section through-hole 376. The gap between the fourth inner shaft member 170 and the second outer shaft member 180 is kept constant by the fifth coupler member 370. [

It is understood that one coupling gear member and one coupler member are used to maintain a constant spacing between any two adjacent shaft members. For example, the gap between the first inner shaft member 140 and the second inner shaft member 150, which are adjacent to each other, is maintained constant by the first coupling gear member 230 and the first coupler member 330 do.

The plurality of elastic units 430A, 430B ... 480A, 480B elastically press the gear members and coupler members toward the spacing portions 132,142,152,162,172,182 of the shaft members. Each of the elastic units 430A, 430B, 480A, and 480B is provided with a plurality of spring washers held in a compressed state by the nut member 491. [ The shape of these spring washers can be understood from the sectional view SV1 of the elastic unit 430A included in Fig. 7B. Alternatively, each elastic unit 430A, 430B ... 480A, 480B may be composed of one or more coil springs.

A pair of elastic units 440A and 440B mounted on the first inner shaft member 140 will be representatively described.

The above-described spacing portion 142 is formed substantially at the center of the first inner shaft member 140.

The second cover mounting member 141, the second coupler part 355 of the third coupler member 350, the first coupler part 331 of the first coupler member 330, Elastic units 440A are sequentially disposed and they are urged toward the left surface of the spacing portion 142 by fastening the nut member 491. [ By this pressing, the elastic unit 440A is compressed, thereby providing an elastic pressing force to the left surface of the spacing portion 142. [

The first gear portion 231 of the first coupling gear member 230, the second gear portion 255 of the third coupling gear member 250 and the elastic unit 440B are disposed on the right side of the spacing portion 142. [ And these are urged toward the right surface of the spacing portion 142 by fastening the nut member 491. [ By this pressing, the elastic unit 440B is in the compressed state, thereby providing the elastic pressing force to the right surface of the spacing portion 142. [

When an external torque smaller than a threshold value is transmitted to the first inner shaft member 140, the torque in the opposite direction canceling the external torque by the above-described elastic pressing forces provided by the pair of elastic units 440A and 440B The first inner shaft member 140 maintains a fixed state without pivoting motion. In other words, the first inner shaft member 140 is pivoted only when an external torque exceeding the threshold value is applied. Here, the threshold value is adjustable by the tightening operation of the nut members 491.

According to this principle, when the angle between the second device unit 20 and the first device unit 10 is set to a certain angle, the second device unit 20 or the first device unit 10 exceeds the threshold value The specific angle set between the second device unit 20 and the first device unit 10 is maintained as it is, unless an external torque is applied. It can be understood from this that the hinge assembly 100A has a free stop function at a certain angle between 0 and 120 degrees.

Reference numerals 493 and 495 which are not shown indicate spacers and washers.

FIG. 8A is a side view showing one cover member and a pair of cover mounting members coupled thereto, and FIG. 8B is a sectional view taken along the line III-III in FIG. 8A. Here, the cover member is exemplified by the first cover member 31, and the description on the first cover member 31 can be equally applied to the other cover members 32-36.

8A, the cover member 31 is engaged with the first cover mounting member 131 mounted on the first outer shaft member 130 of the hinge assembly 100A. The cover member 31 is also engaged with the first cover mounting member 131 'of the other hinge assembly 100B (see Fig. 5) corresponding to the first cover mounting member 131. [ Thus, the cover member 31 covers the first outer shaft member 130 of the hinge assembly 100A and the corresponding first outer shaft member (not shown) of the hinge assembly 100B.

Referring to Fig. 8B, the cover member 31 is composed of three portions 31A, 31B and 31C. Wherein the first portion 31A is coupled to the first cover mounting member 131 through at least one of the screw members. The second portion 31B is bonded to the upper side of the first portion 31A, and the above-mentioned maximum angular crystal face 31a is formed. The third portion 31C is coupled to the lower portion of the first portion 31A and covers the screw members used for fastening the first portion 31A and the first cover mounting member 131. [

Hereinafter, the operation of the above-described hinge assembly 100A will be described.

When the second device unit 20 is folded, the plurality of shaft members 130-180 of the hinge assembly 100A, as shown in Figs. 9A, 9B, and 9C, have an aligned arrangement along a straight line.

In this state, when the user applies a torque in the B direction exceeding the threshold value to the second device unit 20, the torque is transmitted to the shaft members 130-180 of the hinge assembly 100A by the gear unit 200 . Thus, as shown in FIG. 10A, the shaft members 130-180 exhibit pivotal movements relative to one another, and the combination of these pivotal movements results in pivotal movement along the B direction of the second device unit 20 .

During this pivoting motion, relative pivotal movement also occurs between the engaged gear members. Specifically, as shown in FIG. 10B, the first coupling gear member 230 pivots clockwise (in the direction B) about the first outer gear member 210, and the second coupling gear member 240 Is pivoted clockwise about the first coupling gear member 230 and the second outer gear member 220 pivots clockwise about the second coupling gear member 240. At the same time, as shown in Fig. 10C, the fourth coupling gear member 260 pivots clockwise about the third coupling gear member 250, and the fifth coupling gear member 270 pivots clockwise 4 coupling gear member 260 in a clockwise direction.

When the second device unit 20 has an inclined arrangement with respect to the first device unit 10 as shown in Fig. 4, the cover unit 30 covering the hinge assembly 100A, as if it is a single flexible member The second device unit 20 gives a feeling of being smoothly connected to the first device unit 10. In this case, This effect is obtained because the relative pivotal movements between the shaft members 130-180 are caused by the gear engagement between the gear members 210-270, not along any path, but along a certain specified path.

The hinge assembly 100A according to the first embodiment can be similarly applied to the portable electronic device 1A according to the second embodiment described later and shown in Fig.

According to the portable electronic device 1 according to the first embodiment described above, the torque is transmitted through the gear unit 200 to allow the plurality of shaft members 130-180 to pivot with respect to each other, 20 and the first device unit 10 can be made to feel as if they are connected by a single flexible member, thereby improving the appearance of the portable electronic device 1 from the viewpoint of aesthetics as compared with the prior art.

According to the portable electronic device 1 according to the first embodiment, the hinge assembly 100A has a free stop function by the elastic units 430A, 430B, 480A, and 480B, 10) and the second device unit 20 can be maintained as they are. And the elastic forces provided by the elastic units 430A, 430B ... 480A and 480B can be adjusted by the nut members 491. Therefore, the adjustment of the threshold value of the torque enabling the pivot of the second device unit 20 Can be easily performed.

11 to 14 show a portable electronic device 1A according to a second embodiment of the present invention, in which the portable electronic device 1A is illustrated as a laptop computer.

The portable electronic device 1A includes a first device unit 50, a second device unit 60, and a cover unit 70. [

The first device unit 50 constitutes a main body portion of the portable electronic device 1A and includes a plurality of input keys 53 and a touch pad 54. [ The first device unit 50 includes a control unit (not shown) for controlling the operation of the portable electronic device 1A.

The second device unit 60 constitutes a display portion of the portable electronic device 1A and is provided with a display screen 63. [

The second device unit 60 is pivotable about the pivot axis P2 (see Fig. 13) with respect to the first device unit 50. Fig. That is, the second device unit 60 can be pivoted in a direction (direction A) in which it is pivoted or folded in an unfolding direction (direction B). Thus, the second device unit 60 can be arranged at various angles with respect to the first device unit 50 ranging from 0 DEG to 180 DEG. By way of example, as shown in FIGS. 11 and 12, the second device unit 60 may be disposed in a fully unfolded state and have an angle of 180 degrees with respect to the second device unit 60. As another example, as shown in FIGS. 13 and 14, the second device unit 60 may be disposed at an angle of 90 degrees with respect to the first device unit 50.

The cover unit 70 is for covering the hinge assemblies to be described later so that they are not seen from the outside. The cover unit 70 is disposed between the upper end 57 of the first display unit 50 and the lower end 61 of the second display unit 60 and includes five cover members 71-75. The second cover member 72, the third cover member 73, the fourth cover member 74, and the second cover member 71 are arranged in the order close to the upper end 57 of the first device unit 50, And the fifth cover member 75, respectively.

Referring to Fig. 14, each cover member 71-75 has a maximum angular crystal face. That is, the first cover member 71 has the maximum angular crystal face 71a, the second cover member 72 has the maximum angular crystal faces 72a and 72b, and the third cover member 73 has the maximum angular crystal faces 73a and 73b and the fourth cover member 74 has the maximum angular crystal faces 74a and 74b and the fifth cover member 75 has the maximum angular crystal face 35a.

1 and 2, when the second device unit 60 is disposed at an angle of 180 degrees with respect to the first device unit 50, each of the maximum angular crystal planes has at least one maximum angular crystal plane / RTI > For example, the maximum angular crystal face 71a of the first cover member 71 contacts the maximum angular crystal face 72a of the neighboring second cover member 72, and the maximum angular crystal face 71a of the third cover member 73 73a contact the maximum angular crystal face 72b of the neighboring second cover member 72. [ The maximum angle between the second device unit 60 and the first device unit 50 is limited to 180 degrees as shown in FIG. 12 by the contact between these maximum crystal faces.

In this embodiment, the maximum angle between the second device unit 60 and the first device unit 50 is exemplified as being 180 [deg.], But in an alternative embodiment, the shapes of the cover members 71-75 are changed, May have different values (e.g., 270 degrees, 360 degrees, etc.).

15 showing the portable electronic device 1A by omitting the cover unit 70, the portable electronic device 1A includes two hinge assemblies 500A and 500B spaced from each other in the direction of the pivot axis P2 . Pivotal movement between the first device unit 60 and the first device unit 50 can be obtained by these hinge assemblies 500A, 500B.

In this embodiment, the portable electronic device 1A is exemplified as adopting the two hinge assemblies 500A and 500B, but in the alternative, the portable electronic device 1A may employ only one hinge assembly or three or more hinge assemblies .

The hinge assembly 500A and the other hinge assembly 500B have exactly the same structure. Accordingly, the hinge assembly 500A will be described below in an exemplary fashion, and the structure of the other hinge assembly 500B can be easily understood from the description of the hinge assembly 500A.

16, 17A, and 17B, the hinge assembly 500A includes first and second fixed units 510 and 520, a plurality of shaft members 610-690, a gear unit 700, Coupler members 810A, 810B, ..., 860A and 860B and a plurality of elastic units 910,920A, 920B, ..., 980A, 980B, and 990.

The first fixing unit 510 is for fixing the hinge assembly 500A to the first device unit 50. [ The first fixing unit 510 includes a first fixing member 510A and a second fixing member 510B. In alternative embodiments, the first and second fastening members 510A, 510B may be integrally formed.

Two screw through holes 511a and 512a are formed in the first fixing member 510A and two screw through holes 511b and 512b are formed in the second fixing member 510B. Through one screw member (not shown) passing through the screw through holes 511a and 511b and another screw member (not shown) passing through the screw through holes 512a and 512b, The fixing members 510A and 510B are fixed to the first device unit 50. [

The second fixing unit 520 is for fixing the hinge assembly 500A to the second device unit 60. [ The second fixing unit 520 includes a third fixing member 520A, a fourth fixing member 520B, and a fifth fixing member 520C. In alternative embodiments, the third, fourth, and fifth fixing members 520A, 520B, and 520C may be integrally formed.

The third fixing member 520A has two screw through holes 521a and 522a and the fourth fixing member 520B has two screw through holes 521b and 522b. Through one screw member (not shown) passing through the screw through holes 521a and 521b and another screw member (not shown) passing through the screw through holes 522a and 522b, The fixing members 520A and 520B are fixed to the second device unit 60. [

The plurality of shaft members 610-690 includes first and second outer shaft members 610,690 disposed outermost and seven inner shaft members 620,690 disposed between these outer shaft members 610,690. -680). The seven inner shaft members 620-680 include a first inner shaft member 620, a second inner shaft member 630, a third inner shaft member 640, a fourth inner shaft member 650, The inner shaft member 660, the sixth inner shaft member 670, and the seventh inner shaft member 680, respectively.

The plurality of shaft members 610-690 are arranged parallel to the pivot axis P2 (see Fig. 13). And the gap between any two adjacent shaft members of the plurality of shaft members 610-690 is kept constant.

17A, a first mounting hole 513a of a non-circular section and a second mounting hole 514a of a circular section are formed in the first fixing member 510A. The second fixing member 510B is formed with two through holes 513b and 514b corresponding to the first and second mounting holes 513a and 514a. The first outer shaft member 610 is fixedly attached to the first fixing member 510A by being disposed to pass through the first mounting hole 513a of the non-circular cross section. On the other hand, the first inner shaft member 620 is rotatably mounted on the first fixing member 514a by being disposed to pass through the second mounting hole 514a having a circular section.

Here, since the first outer shaft member 610 and the first inner shaft member 620 adjacent to the first outer shaft member 610 are mounted on the common first fixing member 510A, the gap between the first inner shaft member 610 and the first inner shaft member 620 is maintained constant.

17A, a third mounting hole 523a of a non-circular section and a fourth mounting hole 524a of a circular section are formed in the above-described third fixing member 520A. A through hole 523b corresponding to the third mounting hole 523a is formed in the fourth fixing member 520B and a through hole 523c corresponding to the third mounting hole 523a is formed in the fifth fixing member 520C. And a through hole 524b corresponding to the fourth mounting hole 524a are formed. The second outer shaft member 690 is fixedly attached to the third fixing member 520A by being arranged to pass through the through holes 523b and 523c having the non-circular cross-sections and the third mounting hole 523a. On the other hand, the seventh inner shaft member 680 is rotatably mounted to the third fixing member 520A by being disposed to pass through the through hole 524b having the circular cross-sections and the fourth mounting hole 524a.

Here, since the second outer shaft member 690 and the seventh inner shaft member 680 adjacent to the second outer shaft member 690 are mounted on the common third fixing member 520A, it can be seen that the interval between them is kept constant.

A corresponding one of the cover mounting members 631, 641, 651, 661, 671 is mounted on the approximately middle portion of each of the second to sixth inner shaft members 630, 640, 650, 660, Each of the cover mounting members 631, 641, 651, 661, 671 is disposed so as to surround the corresponding second to sixth inner shaft members 630, 640, 650, 660, 670. In other words, the second to sixth inner shaft members 630, 640, 650, 660, 670 are arranged to pass through the corresponding cover mounting members 631, 641, 651, As shown in Fig. 17A, through-holes 631a, 641a, 651a, 661a and 671a penetrating through the second to sixth inner shaft members 630, 640, 650, 660 and 670 are formed in the respective cover mounting members 631, 641, 651, .

17A, each of the through holes 631a, 641a, 651a, 661a, and 671a has a non-circular cross section, and each of the through holes 631a, 641a, 651a, 661a, (630, 640, 650, 660, 670) also have non-circular cross-sections corresponding thereto. Thus, each of the cover mounting members 631, 641, 651, 661, 671 is immovably fixed to each of the corresponding shaft members 630, 640, 650, 660, 670.

Each of the inner shaft members 620-680 is formed with cylindrical spacing portions 622, 632, 642, 652, 662, 672, 682.

The gear unit 700 is mounted to the shaft members 610-690 such that the shaft members 610-690 are connected by gear engagement. This gear unit 700 includes nine gear members in total. More specifically, the gear unit 700 includes first and second outer gear members 710 and 790 and first to seventh inner gear members 720, 730, 740, 750, 760, 770 and 780. These nine gear members 710-790 form one gear train through mutual gear engagement.

When the user applies a torque for pivoting operation to the second device unit 60, the torque is transmitted to each inner shaft member 620-680 by the gear unit 70 so that each inner shaft member 620-680 The pivotal movement of the second device unit 60 can be obtained by making a relative pivotal movement with respect to the other adjacent shaft member.

The first outer gear member 710 is provided with a spur gear having a plurality of gear teeth 711 formed thereon. The first outer gear member 710 is rotatably mounted to the first outer shaft member 610 such that the first outer gear member 710 has a circular cross section penetrating by the first outer shaft member 610 Through holes 712 are formed.

The second outer gear member 790 has the same shape as the first outer gear member 710. The second outer gear member 790 is provided as a spur gear having a plurality of gears 791 formed outside thereof. And the second outer gear member 790 is rotatably mounted to the second outer shaft member 690 such that the second outer gear member 790 has a circular cross section that is penetrated by the second outer shaft member 690 Hole 792 is formed.

The first to seventh inner gear members 720, 730, 740, 750, 760, 770, 780 are provided as spur gears having the same shape. Each of the inner gear members 720, 730, 740, 750, 760, 770, 780 is fixedly coupled to each of the corresponding inner shaft members 620, 630, 640, 650, 660, 670, 680. For this, each of the inner gear members 720, 730, 740, 750, 760, 770, 780 is formed with a through-hole having a non-circular cross section which is penetrated by respective inner shaft members 620, 630, 640, 650, 660, 670, 680 corresponding thereto. By way of example, each inner gear member is formed with a through-hole 722 of non-circular cross section as shown in Fig. 17B.

In this embodiment, the radii of the two outer gear members 710 and 790 are greater than the radii of the seven inner gear members 720-780. However, in alternate embodiments, the radii of the outer gear members 710 and 790 and the radii of the inner gear members 720-780 may be designed to be equal to one another.

The plurality of coupler members 810A, 810B, ..., 860A, 860B are intended to maintain a constant spacing between any two adjacent inner shaft members. Here, the distance between the two shaft members means the distance between the center axes of the two shaft members. For convenience of explanation, the first coupler members 810A and 810B, the second coupler members 820A and 820B, the third coupler members 830A and 830B, the fourth coupler members 840A and 840B, Coupler members 850A and 850B, and sixth coupler members 860A and 860B.

Each coupler member is comprised of a first coupler part rotatably coupled to either one of the inner shaft members and a second coupler part rotatably coupled to the other one of the shaft members adjacent to the shaft member. These first and second coupler parts are integrally formed.

As for the shape of the coupler members, the first coupler member 810A will be described as follows. The first coupler member 810A includes a first coupler part 811 and a second coupler part 815. The first and second coupler parts 811 and 815 are integrally formed. The first coupler part 811 is formed with a through hole 812 of a circular section through which the first inner shaft member 620 passes and the second coupler part 815 is provided with a second inner shaft member 630 A through hole 816 having a circular cross section is formed. The spacing between the first and second inner shaft members 620, 630 connected by the first coupler member 810A is maintained constant.

Two neighboring inner shaft members are connected by two coupler members. For example, referring to neighboring first and second inner shaft members 620 and 630, these first and second inner shaft members 620 and 630 are spaced apart by a pair of first coupler members 810A and 810B It remains constant.

The plurality of elastic units 910, 920A, 920B, ..., 980A, 980B, 990 include first and second outer elastic units 910, 990 provided in the first and second outer shaft members 610, 980A, and 980B provided in the seventh to eighth inner shaft members 620 to 680. The first to seventh inner elastic units 920A, 920B,.

The elastic pressing force provided by the first outer elastic unit 910 generates a frictional force between the first fixing member 510A and the first outer gear member 710 and this frictional force is generated by the rotation of the first outer gear member 710 Lt; RTI ID = 0.0 > a < / RTI > In this embodiment, the first outer elastic unit 910 is composed of a plurality of spring washers 911. The shape of the spring washer 911 can be understood from the sectional view SV2 of the first outer elastic unit 910 included in Fig. 17B.

In an alternative embodiment, the first outer elastic unit 910 may be comprised of a coil spring. Each of the spring washers 911 is held in a compressed state by a nut member 503 fastened to the first outer gear member 710.

The elastic pressing force provided by the second outer elastic unit 990 generates a frictional force between the third fixing member 520A and the second outer gear member 790 and this frictional force is generated by the rotation of the second outer gear member 790 Lt; RTI ID = 0.0 > a < / RTI > In this embodiment, the second outer elastic unit 990 is constituted by a plurality of spring washers 991, but in an alternative embodiment, the second outer elastic unit 990 may be constituted by a coil spring. Each spring washer 991 is held in a compressed state by a nut member 503 fastened to the second outer gear member 790.

By the elastic pressing force provided by the first to seventh inner elastic units 920A, 920B, ..., 980A, 980B, the first to seventh inner gear members 720-780 and the first to seventh inner shaft members 720-780, Frictional forces are generated between the spacing portions 622-682 of the first to seventh inner gear members 720-780, and these frictional forces contribute to the generation of the torque limiting the rotation of the first to seventh inner gear members 720-780. In this embodiment, each inner elastic unit is composed of a plurality of spring washers like the above-described first and second outer elastic units.

Even if an external torque smaller than the threshold value is applied to the second device unit 60 when the second device unit 60 is set at a specific angle within the range of 0 DEG to 180 DEG with respect to the first device unit 50, Movement of the gear members 710-790 does not take place by acting on the gear members 710-790 in the opposite direction of the torque generated by the gears 910, 920A, 920B, ..., 980A, 980B,

The specific angle set between the second device unit 60 and the first device unit 50 is maintained. It will be appreciated that the hinge assembly 500A of this embodiment has a free stop function at a particular angle between 0 and 180 degrees. If an external torque exceeding the threshold value is applied to the second device unit 60, the pivotal movement of the second device unit 60 can be performed. The threshold value is adjustable to an appropriate value by the tightening operation of the nut members 503. [

The parts indicated by reference numerals 505 and 507 which are not shown are spacers and washers.

Fig. 18A is a side view showing one cover member and a pair of cover mounting members coupled thereto, and Fig. 18B is a sectional view taken along line V-V in Fig. Here, the cover member is exemplified by the first cover member 71, and the following description of the first cover member 71 is equally applicable to the other cover members 72-75.

18A, the cover member 71 is engaged with the first cover mounting member 631 mounted on the first inner shaft member 620 of the hinge assembly 500A. The cover member 71 is also engaged with the first cover mounting member 631 'of the other hinge assembly 500B (see Fig. 15) corresponding to the first cover mounting member 631. [ Thus, the cover member 71 covers the first inner shaft member 620 of the hinge assembly 500A and the corresponding first inner shaft member (not shown) of the hinge assembly 500B.

Referring to Fig. 18B, the cover member 71 is composed of three portions 71A, 71B, and 71C. Wherein the first portion 71A is coupled to the first cover mounting member 631 through at least one of the screw members. The second portion 71B and the third portion 71C are coupled to the upper portion and the lower portion of the first portion 71A, respectively, so that the mounting of the cover member 71 is completed.

Hereinafter, the operation of the above-described hinge assembly 500A will be described.

When the second device unit 60 is fully unfolded, the inner shaft members 620-680 of the hinge assembly 500A are aligned along a straight line, as shown in Figs. 19A and 19B.

In this state, when the user applies a torque in the direction A (see Fig. 14) exceeding the threshold value to the second device unit 60, as shown in Figs. 20A and 20B, the inner gear members 720-780 And the inner shaft members 620-680 also exhibit relative pivotal movement in conjunction with the pivotal movement of these inner gear members 720-780.

Specifically, the second inner gear member 730 pivots counterclockwise about the first inner gear member 720, and the third inner gear member 720 740 pivot counterclockwise about the second inner gear member 730 and the fourth inner gear member 750 pivots counterclockwise about the third inner gear member 740, The inner gear member 760 pivots counterclockwise about the fourth inner gear member 750 and the sixth inner gear member 770 pivots counterclockwise about the fifth inner gear member 760, And the seventh inner gear member 780 pivots counterclockwise about the sixth inner gear member 770. The relative pivotal movements of these inner gear members 720-780 are combined and appear as a pivotal movement along the A direction of the second device unit 60. [

When the second device unit 60 is extended from the first device unit 50 as shown in Fig. 14, the cover unit 70 covering the hinge assembly 500A is bent as if a single flexible member bends along a smooth curve And this contributes to the aesthetic design of the portable electronic device 1A. This aesthetic effect is obtained because the relative pivotal movement of the inner shaft members 620-680 occurs along a specific path rather than an arbitrary path through the gear engagement between the gear members 710-790.

The hinge assembly 500A according to the second embodiment is equally applicable to the portable electronic device 1 according to the first embodiment shown in Fig.

In the case of the portable electronic device 1A according to the second embodiment described above, the plurality of inner shaft members 620-680 are pivotally moved with respect to each other by transmitting the torque through the gear unit 700, 60 and the first device unit 50 can be made to feel as if they are connected by a single flexible member, thereby improving the appearance of the portable electronic device 1A from the viewpoint of aesthetics compared to the conventional one.

In the case of the portable electronic device 1A according to the second embodiment, the hinge assembly 500A has a free stop function by the elastic units 910, 920A, 920B, ..., 980A, 980B, and 990 An angle set between the first device unit 50 and the second device unit 60 can be maintained. 980A, 980B, and 990 by the nut members 503 can adjust the elastic forces provided by the elastic units 910, 920A, 920B, ..., 980A, 980B, and 990 so that the torque that enables pivoting of the second device unit 60 Can be easily performed.

1: hinge assembly 10: first device unit
20: second device unit 30: cover unit
100A, 100B: Hinge assembly 110: First fixing unit
120: second fixed unit 200: gear unit
1A: Hinge assembly 50: First device unit
60: second device unit 70: cover unit
500A, 500B: Hinge assembly 510: First fixing unit
520: second fixed unit 700: gear unit

Claims (26)

First and second device units; And
And at least one hinge assembly pivotally connecting the second device unit to the first device unit,
The hinge assembly includes:
A first fixing unit fixed to the first device unit;
A second fixing unit fixed to the second device unit;
A plurality of shaft members arranged in parallel with each other, the first and second outer shaft members being mounted to the first and second fixed units, respectively, and a plurality of inner side members disposed between the first and second outer shaft members, A plurality of shaft members including a shaft member; And
And a gear unit mounted on the shaft members for connecting the plurality of shaft members by gear engagement. The method according to claim 1,
The gear unit includes:
And first and second gear trains arranged in parallel with each other. 3. The method of claim 2,
Wherein the first gear train comprises:
A first outer gear member coupled to the first outer shaft member;
A second outer gear member coupled to the second outer shaft member; And
A first group of coupling gear members mounted on the plurality of inner shaft members, wherein two adjacent shaft members are connected to one another by a coupling gear member, device. The method of claim 3,
The second gear train includes:
And a second group of coupling gear members mounted on the first outer shaft member, the second outer shaft member, and the plurality of inner shaft members. 5. The method of claim 4,
Wherein the total number of the shaft members is N, the number of coupling gear members of the first group is (N / 2) -1, the number of coupling gear members of the second group is N / 2, A portable electronic device which is an even number of natural numbers. 5. The method of claim 4,
Each coupling gear member includes:
A first gear part rotatably coupled to any one of two neighboring shaft members; And
And a second gear part rotatably coupled to the other one of the two shaft members. The method according to claim 6,
Wherein the first outer gear member, the second outer gear member, the first gear part, and the second gear part have the form of a spur gear having the same radius. The method according to claim 1,
The hinge assembly includes:
A plurality of coupler members, wherein two adjacent shaft members further comprise a plurality of coupler members connected by a coupler member. 9. The method of claim 8,
Each of the coupler members,
A first coupler part rotatably coupled to any one of two neighboring shaft members; And
And a second coupler part rotatably coupled to the other of the two shaft members. The method of claim 3,
Each of the shaft members is provided with at least one elastic unit for preventing the second device unit from pivotally moving by an external torque below a threshold value. 11. The method of claim 10,
Wherein the elastic unit comprises a plurality of spring washers which apply an elastic force in the axial direction to the shaft member so as to apply a torque in a direction opposite to the external torque to the shaft member. 3. The method of claim 2,
The gear unit includes:
A first outer gear member mounted to the first outer shaft member;
A second outer gear member mounted on the second outer shaft member; And
A plurality of inner gear members fixedly coupled to each of the inner shaft members,
Wherein the first outer gear member, the second outer gear member, and the plurality of inner gear members form one gear train. 13. The method of claim 12,
Wherein the first outer gear member, the second outer gear member, and the plurality of inner gear members are formed of spur gears of the same radius. 14. The method of claim 13,
The hinge assembly includes:
A plurality of coupler members, wherein two adjacent shaft members further comprise a plurality of coupler members connected by a coupler member. 15. The method of claim 14,
Each of the coupler members,
A first coupler part rotatably coupled to any one of two neighboring shaft members; And
And a second coupler part rotatably coupled to the other of the two shaft members. The method according to claim 1,
Further comprising a cover unit covering the hinge assembly such that the at least one hinge assembly is obscured from the outside. 17. The method of claim 16,
The portable electronic device includes:
A first hinge assembly; And
And a second hinge assembly having the same structure as the first hinge assembly and spaced apart from the first hinge assembly in the pivot axis direction,
The cover unit includes:
And a plurality of cover members covering at least a part of the plurality of shaft members,
Wherein each cover member covers one shaft member of the first hinge assembly and the other shaft member of the second hinge assembly corresponding to the one shaft member. 18. The method of claim 17,
Each of the cover members,
And at least one maximum angular crystal plane that interferes with movement of another neighboring cover member when the second device unit is disposed at the maximum angle with respect to the first device unit. A hinge assembly for pivotably connecting a first device unit and a second device unit of a portable electronic device,
The hinge assembly includes:
A first fixing unit fixed to the first device unit;
A second fixing unit fixed to the second device unit;
A plurality of shaft members arranged in parallel with each other, the first and second outer shaft members being mounted to the first and second fixed units, respectively, and a plurality of inner side members disposed between the first and second outer shaft members, A plurality of shaft members including a shaft member; And
And a gear unit mounted to the plurality of shaft members to connect the plurality of shaft members by gear engagement. First and second device units; And
And at least one hinge assembly pivotally connecting the second device unit to the first device unit,
The hinge assembly includes:
A plurality of shaft members arranged parallel to each other,
Each of the shaft members is provided with at least one elastic unit for applying a torque in the direction opposite to the external torque to the shaft member so as to prevent pivotal movement of the second device unit due to an external torque smaller than a threshold value, . 21. The method of claim 20,
Wherein the elastic unit is constituted by at least one spring washer which provides an axial elastic force to the shaft member to generate a torque in the opposite direction. 21. The method of claim 20,
The hinge assembly includes:
A first fixing unit fixed to the first device unit; And
And a second fixing unit fixed to the second device unit,
The plurality of shaft members
A first outer shaft member mounted to the first fixed unit;
A second outer shaft member mounted on the second fixed unit; And
And a plurality of inner shaft members disposed between the first and second outer shaft members. 21. The method of claim 20,
The hinge assembly includes:
And a gear unit mounted on the shaft members to connect the plurality of shaft members by gear engagement. A hinge assembly for pivotably connecting a first device unit and a second device unit of a portable electronic device,
The hinge assembly includes:
A plurality of shaft members arranged parallel to each other,
Wherein each shaft member is equipped with at least one resilient unit for applying a torque to the shaft member in a direction opposite to the external torque so that pivotal movement of the second device unit by external torque less than a threshold value is prevented. First and second device units;
First and second hinge assemblies of the same construction pivotally connecting the second device unit to the first device unit and spaced apart in the pivot axis direction; And
And a cover unit covering the first and second hinge assemblies,
Each of the hinge assemblies,
A plurality of shaft members arranged parallel to each other,
Wherein the cover unit includes a plurality of cover members covering a part or all of the plurality of shaft members, and each cover member includes one shaft member of the first hinge assembly and the one shaft member corresponding to the one shaft member And another shaft member of the second hinge assembly together. 26. The method of claim 25,
Each of the cover members,
And at least one maximum angular crystal plane that interferes with movement of another neighboring cover member when the second device unit is disposed at the maximum angle with respect to the first device unit.

Images