TWM658228U - Foldable artificial intelligent glasses device - Google Patents

Abstract

A foldable artificial intelligence glasses device includes a pair of frame parts, a pair of lenses, a pair of temple parts, a pair of projection modules, a power supply and control module and a pair of wires. The frame parts are connected to each other, and the lenses are respectively arranged on the frame parts of the frame parts. Each temple piece is connected to the frame piece and the power supply and control module. The projection modules are respectively disposed in the receiving portions of the spectacle frames, and the projection modules respectively project images to the lenses. The power supply and control module is arranged opposite to the frame member, and the power supply and control module includes a control component and a power supply component. Each wire extends from the power supply and control module to the projection module through the hollow tubular structure of the temple piece, so that the power supply and control module and the projection module are electrically connected. The power supply component supplies power to the control component and the projection module.

Description

Foldable artificial intelligence eyewear device

The invention relates to the technical field of a wearable artificial intelligence device, and in particular to a foldable artificial intelligence eyeglass device.

Wearable devices of artificial intelligence include smart watches, smart glasses and other wearable devices. Since these wearable devices need to be powered by electricity, they are mostly equipped with batteries. The batteries of existing smart glasses are arranged on the temples or frames of the glasses, as disclosed in Taiwan Patent M626053 or Taiwan Patent M626675. The batteries arranged on the temples or frames will increase the weight when worn, so long-term wearing will easily cause discomfort to the user's ears, nose or neck. In addition, since the batteries are arranged on the temples or frames, this also limits the size of the batteries, thereby limiting the battery capacity.

In view of this, the purpose of the present invention is to provide a foldable artificial intelligence eyeglass device, which solves the problem of the prior art that the battery is set on the temple or frame of the eyeglasses, causing discomfort to the user, and also solves the problem of limited battery capacity.

An embodiment of the novel foldable artificial intelligence eyeglass device includes a pair of frame components, a pair of lenses, a pair of leg components, a pair of projection modules, a power and control module, and a pair of wires. The frame components are connected to each other, and each frame component includes a frame portion and a receiving portion adjacent to the frame portion. The lenses are respectively arranged in the frame portion of the frame component. Each leg component has a first end and a second end that are arranged opposite to each other, and the first end of each leg component is connected to the frame component, and each leg component has a hollow tubular structure. The projection modules are respectively arranged in the receiving portions of the frame components, and the projection modules project images onto the lenses respectively. The power and control module is disposed between the temple pieces and connected to the second end of the temple pieces, so that the power and control module and the frame piece are disposed opposite to each other, and the power and control module includes a control assembly and a power assembly. Each wire extends from the power and control module through the hollow tubular structure of the temple piece to the projection module, so that the power and control module and the projection module are electrically connected, and the power assembly supplies power to the control assembly and the projection module.

In another embodiment, each lens frame portion includes a lens frame body and a nose pad, the receiving portion and the nose pad are arranged on opposite sides of the lens frame body, and the nose pad abuts against a user's nose.

In another embodiment, the two frame pieces are pivotally connected to each other, and the frame pieces can be rotated to be parallel to each other.

In another embodiment, each temple member includes a first connecting section, a bending section and a second connecting section. The first connecting section is pivoted to the accommodating portion of the frame member via a first pivot structure, the second connecting section is pivoted to the power and control module via a second pivot structure, and two ends of the bending section are pivoted to the first connecting section and the second connecting section via a third pivot structure and a fourth pivot structure respectively, so that the position of the first connecting section is higher than that of the second connecting section.

In another embodiment, the axis of the first hinge structure is parallel to the axis of the second hinge structure, and the axis of the third hinge structure is parallel to the axis of the fourth hinge structure.

In another embodiment, the first connecting section has a first rod and a second rod, the first rod is combined with the second rod to form a first length extension structure; the first rod has a first insertion portion, the second rod has a first sleeve portion, the inner diameter of the first sleeve portion is larger than the outer diameter of the first insertion portion; the outer peripheral surface of the first insertion portion is provided with a plurality of first recesses, the first sleeve portion is provided with a first elastic arm, the end of the first elastic arm is provided with a first protrusion, the first protrusion is engaged with the first recess, so that the first rod and the second rod are positioned at appropriate relative positions.

In another embodiment, the second connecting section has a third rod and a fourth rod, the third rod is combined with the fourth rod to form a second length extension structure; the third rod has a second insertion portion, the fourth rod has a second sleeve portion, the inner diameter of the second sleeve portion is larger than the outer diameter of the second insertion portion; the outer peripheral surface of the second insertion portion is provided with a plurality of second recesses, the second sleeve portion is provided with a second elastic arm, the end of the second elastic arm is provided with a second protrusion, the second protrusion is engaged with the second recess, so that the third rod and the fourth rod are positioned at appropriate relative positions.

In another embodiment, the third rod has a fifth pivot structure, which is located between the fourth pivot structure and the second insertion portion. The fourth rod includes a sixth pivot structure, which is located between the second pivot structure and the second sleeve portion. The axis of the fifth pivot structure is parallel to the axis of the first pivot structure, and the axis of the sixth pivot structure is parallel to the axis of the third pivot structure.

In another embodiment, the first hinge structure, the third hinge structure, the fourth hinge structure, the fifth hinge structure and the sixth hinge structure are solid core hinge structures, the solid core hinge structure includes a core, a shaft body and a sleeve portion, the sleeve portion is sleeved on the shaft body, and the core passes through the shaft body and the sleeve portion; the second hinge structure is a virtual core hinge structure, the virtual core hinge structure includes a plurality of spring plates and an axial hole, the spring plates extend axially and are arranged along a circle to form a virtual core, the virtual core is inserted into the axial hole and the spring plates abut against the hole wall of the axial hole.

In another embodiment, the power and control module includes a housing and a plurality of buttons disposed on the housing, the control component and the power component are disposed on the housing, and the buttons are electrically connected to the control component or the power component.

The foldable artificial intelligence eyeglasses device of the present invention is provided with a power supply and a control module at a relative position of the frame member and connected to the second end of the temple member. When the foldable artificial intelligence eyeglasses of the present invention are worn on the head of the user, the weight of the power supply and the control module can be borne by the head of the user, so that the ears or nose of the user will not feel uncomfortable even if the user wears the eyeglasses for a long time. In addition, since the power supply and the control module are provided separately from the frame member and the temple member, the size and capacity of the power supply assembly are not limited by the structure and can be increased.

Please refer to Figures 1, 2, 3, 4, 5 and 6, which show an embodiment of the foldable artificial intelligence eyeglass device of the present invention. The foldable artificial intelligence eyeglass device 1 of the present embodiment includes a pair of frame members 10, a pair of lenses 20, a pair of lens legs 30, a pair of projection modules 40, a power supply and control module 50 and a pair of wires 60 (as shown in Figures 7 and 9).

The frame members 10 are connected to each other, and each frame member 10 includes a frame portion 11 and a receiving portion 12 adjacent to the frame portion 11. The frame portion 11 includes a frame body 111 and a nose pad 112. One side of the frame body 111 is connected to the receiving portion 12, and the nose pad 112 is disposed on the other side of the frame body 111 and opposite to the receiving portion 12. The nose pad 112 abuts against a user's nose. The lenses 20 are respectively disposed in the frame body 111 of the frame portion 11. As shown in FIG3 , the lens frames 111 of the lens frame parts 11 of the two lens frame members 10 are hinged to each other by a lens frame hinge structure 13. The lens frame hinge structure 13 includes a rotating base 131 and two shafts 132. The two shafts 132 penetrate the rotating base 131 and the lens frame 111, so that the two lens frames 111 can be rotated relative to the rotating base 131 to be parallel to each other (as shown in FIG8 ). The lens frame part 11 and the accommodating part 12 of this embodiment are an integrally formed structure.

Each temple member 30 has a first end 31 and a second end 32 which are arranged opposite to each other. The first end 31 of the temple member 30 is connected to the frame member 10, and the second end 32 of the temple member 30 is connected to the power and control module 50, so that the power and control module 50 is arranged opposite to the frame member 10. Each temple member 30 has a hollow tubular structure (as shown in FIG. 7 ).

The projection modules 40 are respectively disposed in the receiving portion 12 of the frame member 10, and the projection modules 40 respectively project images onto the lens 20 for the user to view. The power and control module 50 includes a housing 51, a control assembly, a power assembly, and a plurality of buttons 52. The control assembly and the power assembly are disposed in the housing 51, and the buttons 52 are electrically connected to the control assembly or the power assembly. Each wire 60 extends from the power and control module 50 through the hollow tubular structure of the temple member 30 to the projection module 40, so that the power and control module 50 and the projection module 40 are electrically connected, and the power assembly supplies power to the control assembly and the projection module 40. The electronic signal of the control assembly is transmitted to the projection module 40 via the wire 60, such as a control signal or image data.

Each temple member 30 includes a first connecting section 33, a bending section 34 and a second connecting section 35. The first connecting section 33 is pivoted to the receiving portion 12 of the frame member 10 via a first pivot structure 71, the second connecting section 35 is pivoted to the power and control module 50 via a second pivot structure 72, and both ends of the bending section 34 are pivoted to the first connecting section 33 and the second connecting section 35 via a third pivot structure 73 and a fourth pivot structure 74, respectively. The axis of the first pivot structure 71 is parallel to the axis of the second pivot structure 72, and the axis of the third pivot structure 73 is parallel to the axis of the fourth pivot structure 74. In this embodiment, the axis of the first hinge structure 71 and the axis of the second hinge structure 72 are in the Z-axis direction, and the axis of the third hinge structure 73 and the axis of the fourth hinge structure 74 are in the X-axis direction.

The bending section 34 is bent downward from the first connecting section 33 to the second connecting section 35, so that the position of the first connecting section 33 is higher than the position of the second connecting section 35, and thus the position of the power and control module 50 is lower than the position of the frame 10. When the user wears the foldable artificial intelligence eyewear device 1 of this embodiment, the temple 30 is supported by the ear, the frame 10 is supported by the nose, and the power and control module 50 is supported by the head. The rotation of the second hinge structure 72 can make the power and control module 50 close to the head, and the friction between the head and the power and control module 50 can offset part of the weight of the power and control module 50.

As shown in FIG8 , by means of the third pivot structure 73 and the fourth pivot structure 74, the bending section 34 can be rotated so that the first connecting section 33, the bending section 34 and the second connecting section 35 are stacked in parallel with each other so that the temple pieces 30 are in a folded state. At the same time, the first pivot structure 71 and the frame pivot structure 13 are rotated so that the two frame pieces 10 are rotated relative to each other to form a state parallel to each other and are folded between the two temple pieces 30.

As shown in FIG. 4 and FIG. 5 , the first connecting section 33 has a first rod 331 and a second rod 332. The first rod 331 is combined with the second rod 332 to form a first length extension structure. The first rod 331 has a first insertion portion 3311, and the second rod 332 has a first sleeve portion 3321. The inner diameter of the first sleeve portion 3321 is larger than the outer diameter of the first insertion portion 3311. The outer peripheral surface of the first insertion portion 3311 is provided with a plurality of first recesses 3312. The first sleeve portion 3321 is provided with a first elastic arm 3322. The end of the first elastic arm 3322 is provided with a first protrusion 3323. The first protrusion 3323 is engaged with the first recess 3312, so that the first rod 331 and the second rod 332 are positioned at appropriate relative positions. Thereby, the first connecting section 33 can be extended or retracted according to the head size of the user.

The second connecting section 35 has a third rod 351 and a fourth rod 352. The third rod 351 is combined with the fourth rod 352 to form a second length extension structure. The third rod 351 has a second insertion portion 3511, and the fourth rod 352 has a second sleeve portion 3521. The inner diameter of the second sleeve portion 3521 is larger than the outer diameter of the second insertion portion 3511. The outer peripheral surface of the second insertion portion 3511 is provided with a plurality of second recesses 3512. The second sleeve portion 3521 is provided with a second elastic arm 3522. The end of the second elastic arm 3522 is provided with a second protrusion 3523. The second protrusion 3523 is engaged with the second recess 3512, so that the third rod 351 and the fourth rod 352 are positioned at appropriate relative positions. Thereby, the second connecting section 35 can be extended or retracted according to the head size of the user.

The third rod 351 has a fifth pivot structure 75, which is located between the fourth pivot structure 74 and the second insertion portion 3511. The fourth rod 352 includes a sixth pivot structure 76, which is located between the second pivot structure 72 and the second sleeve portion 3521. The axis of the fifth pivot structure 75 is parallel to the axis of the first pivot structure 71, which is the Z axis direction. The axis of the sixth pivot structure 76 is parallel to the axis of the third pivot structure 73, which is the X axis direction. The fifth pivot structure 75 has a similar function to the second pivot structure 72, which allows the temple member 30 to bend and fit more closely to the user's head. The sixth hinge structure 76 is used to move the power and control module 50 closer to the temple member 30 for folding (as shown in FIG. 8 ).

The first hinge structure 71, the third hinge structure 73, the fourth hinge structure 74, the fifth hinge structure 75 and the sixth hinge structure 76 are solid core hinge structures, which include a core 711, a shaft portion 712 and a sleeve portion 713. The sleeve portion 713 is sleeved on the shaft portion 712, and the core 711 passes through the shaft portion 712 and the sleeve portion 713 to form a hinge. The second hinge structure 72 is a virtual axis hinge structure, which includes a plurality of springs 721 and an axis hole 722 . The springs 721 extend axially and are arranged along a circle to form a virtual axis. The virtual axis is inserted into the axis hole 722 and the springs 721 abut against the wall of the axis hole 722 .

The foldable artificial intelligence eyeglasses device of the present invention is provided with a power supply and a control module at a relative position of the frame member and connected to the second end of the temple member. When the foldable artificial intelligence eyeglasses of the present invention are worn on the head of the user, the weight of the power supply and the control module can be borne by the head of the user, so that the ears or nose of the user will not feel uncomfortable even if the user wears the eyeglasses for a long time. In addition, since the power supply and the control module are provided separately from the frame member and the temple member, the size and capacity of the power supply assembly are not limited by the structure and can be increased.

However, what is described above is only the preferred embodiment of the present invention, and it cannot be used to limit the scope of the implementation of the present invention. That is, all simple equivalent changes and modifications made according to the scope of the patent application and the description of the present invention are still within the scope of the patent of the present invention. In addition, any embodiment or patent application of the present invention does not have to achieve all the purposes, advantages or features disclosed by the present invention. In addition, the abstract and title are only used to assist in searching for patent documents, and are not used to limit the scope of rights of the present invention. In addition, the terms "first", "second", etc. mentioned in this specification or patent application are only used to name the name of the element or distinguish different embodiments or scopes, and are not used to limit the upper or lower limit of the number of elements.

1: Foldable artificial intelligence eyeglass device 10: Frame member 11: Frame part 12: Accommodation part 13: Frame pivot structure 20: Lens 30: Mirror leg member 31: First end 32: Second end 33: First connecting section 34: Bending section 35: Second connecting section 40: Projection module 50: Power supply and control module 51: Housing 52: Button 60: Wire 71: First pivot structure 72: Second pivot structure 73: Third pivot structure 74: Fourth pivot structure 75: Fifth pivot structure 76: Sixth pivot structure 111: lens frame 112: nose pad 131: rotating base 132: shaft 331: first rod 332: second rod 351: third rod 352: fourth rod 711: shaft core 712: shaft body 713: shaft sleeve 721: spring sheet 722: shaft hole 3311: first insertion part 3312: first recessed part 3321: first sleeve part 3322: first spring arm 3323: first protrusion 3511: second insertion part 3512: second recessed part 3521: second sleeve part 3522: second spring arm 3523: second protrusion

FIG. 1 is a perspective view of an embodiment of the foldable artificial intelligence eyeglass device of the present invention. FIG. 2 is a perspective view of the foldable artificial intelligence eyeglass device of FIG. 1 from another perspective. FIG. 3 is a partial perspective exploded view of the foldable artificial intelligence eyeglass device of FIG. 1. FIG. 4 is a perspective exploded view of the mirror leg of the foldable artificial intelligence eyeglass device of FIG. 1. FIG. 5 is a perspective exploded view of the mirror leg of FIG. 4 from another perspective. FIG. 6 is a top view of the right half of the foldable artificial intelligence eyeglass device of FIG. 1. FIG. 7 is a cross-sectional view of the hollow structure of the mirror leg of the foldable artificial intelligence eyeglass device of the present invention. FIG. 8 is a perspective view of the folded foldable artificial intelligence eyeglass device of the present invention. Figure 9 is a diagram showing a user wearing the novel foldable artificial intelligence eyewear device.

1: Foldable artificial intelligence eyewear device

10:Mirror frame parts

11: Lens frame

12: Accommodation section

20: Lens

30: Mirror leg pieces

31: First end

32: Second end

33: First connection section

34: Bend section

35: Second connection section

40: Projection module

50: Power supply and control module

111:Mirror frame

112: Nose pads

Claims (10)

A foldable artificial intelligence eyeglass device comprises: A pair of frame members (10) connected to each other, each frame member (10) comprising a frame portion (11) and a receiving portion (12) adjacent to the frame portion (11); A pair of lenses (20) respectively arranged on the frame portion (11) of the frame members (10); A pair of leg members (30), each leg member (30) having a first end (31) and a second end (32) arranged opposite to each other, the first end (31) of each leg member (30) being connected to the frame member (10), and each leg member (30) having a hollow tubular structure; A pair of projection modules (40), respectively disposed in the receiving portions (12) of the lens frame (10), the projection modules (40) respectively project images onto the lenses (20); A power and control module (50), disposed between the lens legs (30) and connected to the second ends (32) of the lens legs (30), such that the power and control module (50) and the lens frame (10) are disposed opposite to each other, the power and control module (50) comprising a control component and a power component; and A pair of wires (60), each of which extends from the power and control module (50) through the hollow tubular structure of the mirror leg (30) to the projection module (40), so that the power and control module (50) and the projection module (40) are electrically connected, and the power supply assembly supplies power to the control assembly and the projection modules (40). A foldable artificial intelligence eyewear device as described in claim 1, wherein each of the lens frame portions (11) includes a lens frame body (111) and a nose pad (112), the accommodating portion (12) and the nose pad (112) are arranged on opposite sides of the lens frame body (111), and the nose pad (112) abuts against the nose of a user. A foldable artificial intelligence eyewear device as described in claim 2, wherein two of the frame parts (10) are pivotally connected to each other, and the frame parts (10) can be rotated to be parallel to each other. A foldable artificial intelligence eyeglass device as described in claim 1, wherein each of the temple parts (30) includes a first connecting section (33), a bending section (34) and a second connecting section (35), the first connecting section (33) is pivotally connected to the accommodating portion (12) of the frame part (10) via a first pivoting structure (71), the second connecting section (35) is pivotally connected to the power and control module (50) via a second pivoting structure (72), and the two ends of the bending section (34) are pivotally connected to the first connecting section (33) and the second connecting section (35) via a third pivoting structure (73) and a fourth pivoting structure (74), respectively, so that the position of the first connecting section (33) is higher than that of the second connecting section (35). A foldable artificial intelligence eyewear device as described in claim 4, wherein the axis of the first pivot structure (71) is parallel to the axis of the second pivot structure (72), and the axis of the third pivot structure (73) is parallel to the axis of the fourth pivot structure (74). A foldable artificial intelligence eyewear device as described in claim 4, wherein the first connecting section (33) has a first rod (331) and a second rod (332), the first rod (331) is combined with the second rod (332) to form a first length extension structure; the first rod (331) has a first insertion portion (3311), the second rod (332) has a first sleeve portion (3321), the inner diameter of the first sleeve portion (3321) is greater than The outer diameter of the first insertion portion (3311); the outer peripheral surface of the first insertion portion (3311) is provided with a plurality of first recesses (3312); the first sleeve portion (3321) is provided with a first elastic arm (3322); the end of the first elastic arm (3322) is provided with a first protrusion (3323); the first protrusion (3323) is engaged with the first recesses (3312), so that the first rod (331) and the second rod (332) are positioned at appropriate relative positions. A foldable artificial intelligence eyewear device as described in claim 6, wherein the second connecting section (35) has a third rod (351) and a fourth rod (352), the third rod (351) is combined with the fourth rod (352) to form a second length extension structure; the third rod (351) has a second insertion portion (3511), the fourth rod (352) has a second sleeve portion (3521), the inner diameter of the second sleeve portion (3521) is greater than The outer diameter of the second insertion portion (3511); the outer peripheral surface of the second insertion portion (3511) is provided with a plurality of second recesses (3512); the second sleeve portion (3521) is provided with a second elastic arm (3522); the end of the second elastic arm (3522) is provided with a second protrusion (3523); the second protrusion (3523) is engaged with the second recesses (3512), so that the third rod (351) and the fourth rod (352) are positioned at appropriate relative positions. A foldable artificial intelligence eyewear device as described in claim 7, wherein the third rod (351) has a fifth pivot structure (75), the fifth pivot structure (75) is located between the fourth pivot structure (74) and the second insertion portion (3511), the fourth rod (352) includes a sixth pivot structure (76), the sixth pivot structure (76) is located between the second pivot structure (72) and the second sleeve portion (3521), the axis of the fifth pivot structure (75) is parallel to the axis of the first pivot structure (71), and the axis of the sixth pivot structure (76) is parallel to the axis of the third pivot structure (73). The foldable artificial intelligence eyewear device as described in claim 8, wherein the first hinge structure (71), the third hinge structure (73), the fourth hinge structure (74), the fifth hinge structure (75) and the sixth hinge structure (76) are solid axis hinge structures, and the solid axis hinge structure includes an axis (711), an axis portion (712) and an axis sleeve portion (713), and the axis sleeve portion (713) is sleeved on the axis portion (712). , the shaft core (711) passes through the shaft body (712) and the shaft sleeve (713); the second hinge structure (72) is a virtual shaft core hinge structure, which includes a plurality of spring sheets (721) and an axial hole (722), the spring sheets (721) are axially extended and arranged along a circle to form a virtual shaft core, the virtual shaft core is inserted into the axial hole (722) and the spring sheets (721) are in contact with the hole wall of the axial hole (722). A foldable artificial intelligence eyewear device as described in claim 1, wherein the power and control module (50) includes a housing (51) and a plurality of buttons (52) disposed on the housing (51), the control component and the power component are disposed on the housing (51), and the buttons (52) are electrically connected to the control component or the power component.

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