KR102348164B1 - Slim Type Hinge Apparatus - Google Patents

Abstract

The present invention relates to a slim hinge device.
The present invention provides a hinge device for providing relative rotation of a first member and a second member, comprising: a gear unit coupled to the first member and the second member to rotate, and comprising a plurality of gears rotating in opposite directions; and a disk spring providing an elastic force to control the rotation of the first member and the second member when the plurality of gears rotate,
The disk spring may be provided with a slim hinge device connected to the rotation shaft of the plurality of gears to provide an elastic force.

Description

Slim Type Hinge Apparatus

The present invention relates to a slim hinge device.

A hinge device may be provided on a folding part of various display devices such as a notebook computer and a foldable portable electronic device, and a reliable rotation operation should be performed without shaking during unfolding and folding operations of the display device.

In addition, the hinge device of the display device may limit the ability to minimize the bezel portion of the display unit while maintaining a predetermined torque in its structure.

Therefore, a method for reducing the overall width of the hinge device needs to be devised.

Accordingly, the present invention was invented to solve the above problems, and the problem to be solved by the present invention is to reduce the width of the hinge device and to reduce the bezel portion of the display unit by a minimum disk spring. will provide

A solution means of the present invention is a hinge device that provides relative rotation of a first member and a second member, a gear unit comprising a plurality of gears coupled to the first member and the second member to rotate and rotate in opposite directions ; and a disk spring providing an elastic force to control the rotation of the first member and the second member when the plurality of gears rotate,

The disk spring may be provided with a slim hinge device connected to the rotation shaft of the plurality of gears to provide an elastic force.

As described above, the hinge device according to the present invention has a structure in which the disk spring is connected to the rotation shaft of a plurality of gears, and since the area providing elastic force is increased and the thickness of the brackets supporting both sides of the disk spring can be reduced, the hinge device can reduce the overall width of

By reducing the overall width of the hinge device according to the present invention, for example, when installed in a notebook computer, the bezel portion of the display unit can be reduced, and accordingly, the display unit can be enlarged in the case of the same size.

In addition, in the present invention, since the disk spring is connected as if connecting one plate across the rotational shafts of a plurality of gears, it is possible to reduce the number of disk springs compared to the structure in which the disk springs are coupled to each rotational shaft. In spite of reducing the number, it is possible to generate the same torque as the structure having each disc spring.

In addition, since the hinge device according to the present invention can maintain the distance between the rotation shafts by the disk spring, the rigidity of the hinge device can be increased.

1 is a partially exploded perspective view of a hinge device according to the present invention.
2 is a plan view of the hinge device according to the present invention, except for the hinge cover.
3 is a perspective view of a disk spring according to the present invention.
4 is a front view of a disk spring according to the present invention.
5 is a side view of a disc spring according to the present invention;

Hereinafter, specific contents for carrying out the present invention will be described in detail based on the accompanying exemplary drawings.

1 is a partially exploded perspective view of a hinge device according to the present invention, and FIG. 2 is a plan view of the hinge device according to the present invention except for the hinge cover.

1 and 2 , the hinge device 100 according to the present invention includes a first support member 110 , a plurality of gear units 120 for rotation, a second support member 130 , and a plurality of third 3 includes a support member 132 , a first bracket 140 , one or more disk springs, that is, a first disk spring 150 , a second disk spring 160 , a second bracket 170 , and a hinge cover 180 . can do.

The gear unit 120 is a first gear 121 and a second gear 122 that face each other and rotate in opposite directions, and a third gear that meshes between the first gear 121 and the second gear 122 . (123), the third gear 123 may be configured as a fourth gear engaged with the lower portion. Gears provided in the gear unit 120 may be arranged in an even number, and may be rotated at the same angle to each other.

The first gear 121 and the second gear 122 may be provided in a state spaced apart by the third gear 123 and the fourth gear, which are intermediate gears.

The third gear 123 and the fourth gear may be displaced in one direction instead of being disposed to be meshed with each other on the same vertical line.

Here, the hinge device 100 according to the present invention may be provided with a disk spring that controls rotation for the unfolding and folding operations of the display device. The disk spring includes the first disk spring 150 and the second disk facing each other. It may be formed of a spring 160 .

The first disk spring 150 may be supported by being coupled to a pair of first and second rotation shafts 121a and 122a of the first gear 121 and the second gear 122 , respectively.

The first rotation shaft 121a and the second rotation shaft 122a of the pair of first gear 121 and the second gear 122 may be coupled to and supported by the second disk spring 160 , respectively.

Referring to FIG. 1 , both side surfaces of the first rotation shaft 121a and the second rotation shaft 122a may be formed as flat portions, and the remaining surfaces may be formed as curved portions.

Referring to FIG. 2 , the first rotation shaft 121a and the second rotation shaft 122a may be linked to each other through the connection member 102 , respectively, to the display unit and the main body of the notebook computer as a display device. In addition, each of the display units of the foldable display device may be connected to each other through the connecting member 102 .

In Fig. 2, the connecting member 102 is schematically shown in a folded state.

The first disk spring 150 and the second disk spring 160 are coupled through the first rotational shaft 121a and the second rotational shaft 122a of the first gear 121 and the second gear 122 to be rotatably penetrated. A pair of coupling holes 151 and 161 may be formed respectively, and coupling holes 152 and 162 for fixing may be formed between the coupling holes 151 and 161 .

Referring to FIG. 1 , the third rotation shaft 123a of the third gear 123 and the fourth rotation shaft 124a of the fourth gear 124 may be rotatably coupled to the first support member 110 .

3 and 5 , elastic parts 153 and 163 may be provided on one surface of the first disk spring 150 and the second disk spring 160 , respectively. Each of the elastic parts 153 and 163 may be formed to protrude from one side along the circumferential surface of each of the coupling holes 151 and 161 and the coupling holes 152 and 162 .

In the present invention, a member connected to the first rotation shaft 121a of the first gear 121 and a member connected to the second rotation shaft 122a of the second gear 122 may be rotated.

For example, in the case of a notebook computer, the member connected to the first rotation shaft 121a of the first gear 121 is a first member, and a member connected to the display unit and the second rotation shaft 122a of the second gear 122 . may be the body portion as the second member, or vice versa.

Also, as another example, in the case of a foldable display device, a first member connected to the first rotation shaft 121a of the first gear 121 and a second member connected to the second rotation shaft 122a of the second gear 122 . Each of the two members may be either side of the flexible display unit.

The hinge device 100 of the present invention may be rotated when an unfolding operation and a folding operation are performed. At this time, the first gear 121 and the second gear 122 are simultaneously rotated in opposite directions, and the first gear 121 ) and the third gear 123 and the fourth gear 124, which are intermediate gears engaged between the second gear 122, may also be rotated in opposite directions at the same time.

In other words, when one end of the first rotation shaft 121a and the second rotation shaft 122a passing through the fixed first support member 110 rotates, respectively, the first gear 121 and the second gear 122 . may be rotated.

At this time, since the other end of the first rotation shaft 121a and the second rotation shaft 122a passes through the second support member 130 , in the end both the first rotation shaft 121a and the second rotation shaft 122a The end side may be stably rotated while being supported by the fixed first support member 110 and the second support member 130 .

One end of the first rotation shaft 121a and the second rotation shaft 122a passes through the second support member 130 , and the pair of third support members 132 , the first bracket 140 , and the first disk spring 150 . ), the second disk spring 160 , and the second bracket 170 may all be passed through.

The third support member 132 may be formed in a circular shape like a washer, and may be coupled to the first rotation shaft 121a and the second rotation shaft 122a to be penetrated, respectively. The first rotation shaft 121a and the second rotation shaft 122a have a structure in which both sides are flat rather than circular in cross section, and the third support member 132 through which the first rotation shaft 121a and the second rotation shaft 122a pass. Since the through-holes of the first and second rotation shafts 121a and 122a have the same structure, they can be rotated simultaneously when the first rotation shafts 121a and the second rotation shafts 122a are rotated.

Therefore, when one end of the first rotation shaft 121a and the second rotation shaft 122a rotates, only the pair of third support members 132 rotate at the same time, and the remaining components of the first bracket 140 and the first disk The spring 150, the second disk spring 160, and the second bracket 170 may maintain a fixed state, and the first disk spring 150 and the second disk spring 160 may be in a state of providing an elastic force. can

Then, when the first gear 121 and the second gear 122 rotate, the first disk spring 150 and the second disk spring 160 have elastic force acting on them, so that the rotational state may be controlled.

Here, since the first disk spring 150 and the second disk spring 160 have a structure connected across the first gear 121 and the second gear 122, the disk spring is divided into the first gear 121 ) and the second gear 122 may provide a greater elastic force compared to a structure independently coupled to the first rotation shaft 121a and the second rotation shaft 122a, respectively.

In other words, the first disk spring 150 and the second disk spring 160 are divided into the first and second rotation shafts 121a and 122a of the first gear 121 and the second gear 122, respectively. Compared to the combined structure, the area providing the elastic force may be increased.

In addition, referring to FIG. 4 , the first disk spring 150 and the second disk spring 160 are the first and second rotation shafts 121a and 122a of the first gear 121 and the second gear 122 . ), since it is a structure continuously connected to the first rotation shaft 121a and the second rotation shaft 122a, the distance L between the center C of the rotation shaft 122a can always be kept constant, and accordingly, the rigidity as the hinge device 100 can be improved. can reinforce

Referring to FIG. 2 , in the hinge device 100 according to the present invention, a first bracket 140 and a second bracket 170 respectively provided on one side of the first disk spring 150 and the second disk spring 160 . ), because elasticity is provided and rigidity is maintained even if the thickness is reduced, the overall width (W) can be reduced, and then, for example, when installed in a notebook computer, the bezel portion of the display unit can be reduced, so that in the case of the same size It can provide a larger screen.

The first rotation shaft 121a and the second rotation shaft 122a of the first gear 121 and the second gear 122 are a second support member 130 , a third support member 132 , and a first bracket 140 . , passing through the first disk spring 150 , the second disk spring 160 and the second bracket 170 , and may be coupled by a nut 190 .

In addition, the first bracket 140 , the first disk spring 150 , the second disk spring 160 , and the second bracket 170 may be stably coupled through a fastening member 192 such as a coupling pin.

When the gear unit 120 rotates, the second bracket 170 is blocked in one direction by the fixed nut 190 to be in a fixed state, so the first disk spring 150 and the second disk spring 160 are fixed. The elastic force may act in the direction of the gear unit 120 through the first bracket 140 . Accordingly, the hinge device 100 of the present invention can reliably control rotation during unfolding and folding operations of various display devices.

100... Hinge device 102... Connection member
110... first support member
120... Gear unit 121... 1st gear
121a... 1st rotation shaft 122... 2nd gear
122a... Second rotation shaft 123... Third gear
124... 4th gear
123a... Third axis of rotation 124a... Fourth axis of rotation
130... second support member 132... third support member
140... 1st bracket 150... 1st disc spring
160... 2nd disc spring 170... 2nd bracket
180... Hinge cover190... Nut
192... Fastening memberL... Distance
W... width

Claims (5)

A hinge device for providing relative rotation of a first member and a second member, the hinge device comprising:
a gear unit coupled to the first member and the second member to rotate, and comprising a plurality of gears engaged;
a disk spring providing an elastic force to control the rotation of the first member and the second member when the plurality of gears rotate;
including,
The plurality of gears are coupled to the first member and the second member to be rotated, a first gear and a second gear coupled to a first rotation shaft and a second rotation shaft, respectively;
It includes a third gear and a fourth gear meshed between the first gear and the second gear,
The disk spring includes a first disk spring and a second disk spring through which the first rotation shaft and the second rotation shaft pass,
The first disk spring and the second disk spring are each formed with a pair of coupling holes through which the first rotation shaft and the second rotation shaft pass,
The first disk spring and the second disk spring have an elastic part protruding from one surface, and the elastic part is arranged to face each other,
The first and second disk springs are supported on side surfaces of the first and second disk springs in the direction of the first and second rotation axes to support the first and second disk springs. A first bracket and a second bracket are respectively provided to receive the elastic force of
On the side of the first bracket in the direction of the gear unit,
A pair of third support members are provided in which the first rotation shaft and the second rotation shaft are coupled through, respectively, and are rotated simultaneously when the first rotation shaft and the second rotation shaft rotate,
When the first rotation shaft and the second rotation shaft rotate,
In a state in which the first bracket, the first disk spring, the second disk spring and the second bracket are fixed, the pair of third support members are rotated at the same time while the first disk spring and the second disk spring are fixed to each other. A slim hinge device provided with an elastic force by the facing elastic part.
According to claim 1,
The first and second rotational shafts are supported through the pair of coupling holes formed in the first and second disk springs, so that the first disk spring extends from the first rotational shaft to the second rotational shaft. And a slim hinge device in which the elastic force by the elastic part of the second disk spring is provided at the same time.
According to claim 1,
The elastic part is a slim hinge device formed to protrude to one side along the circumferential surface of the coupling hole.
According to claim 1,
A slim hinge device in which the first disk spring and the second disk spring are coupled and fixed by a fastening member.
According to claim 1,
The first disk spring and the second disk spring are connected between the first rotation shaft and the second rotation shaft coupled to the first gear and the second gear, respectively, to maintain a distance between the first rotation shaft and the second rotation shaft Slim hinge unit.

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