CN112394520A - Main body device of head-mounted equipment and head-mounted equipment - Google Patents

Abstract

The invention discloses a main body device of head-mounted equipment and the head-mounted equipment, wherein the main body device comprises a first shell and a host, and an air outlet is arranged at least one of two ends of the first shell along the length extension direction of the first shell; the host is accommodated in the first shell, at least one air duct is arranged between the host and the first shell, the air duct is communicated with the air outlet, and heat generated by the host is transmitted to the air outlet through the air duct and is discharged. According to the main body device of the head-mounted equipment and the head-mounted equipment disclosed by the embodiment of the invention, the air channel is utilized to transmit the heat generated by the host to the air outlet, so that the heat is not required to be transmitted to the shell, the shell is prevented from being heated, the problem that the use experience of a user is influenced because the part of the shell, which is in contact with the user, is heated and heated in the related art is solved, and the use experience of the user is effectively improved.

Description

Main body device of head-mounted equipment and head-mounted equipment

Technical Field

The invention relates to the technical field of head-mounted equipment, in particular to a main body device of the head-mounted equipment and the head-mounted equipment.

Background

Head-mounted equipment such as AR (augmented Reality) glasses, VR (Virtual Reality) glasses etc. are provided with optics, electronic module because of inside, and these modules often can produce the heat in the operation, need in time arrange the outside or conduct other regions with the heat to avoid the inside heat gathering of equipment and influence the condition of equipment normal operating. In the related art, the head-mounted device mostly adopts a mode of attaching graphite sheets to optical and electronic modules so as to bring heat to a device shell, and the device shell is utilized to exchange heat with the outside, so that the purpose of cooling is achieved. However, in this way, on the one hand, the heat dissipation effect is not ideal, and on the other hand, the temperature of the device housing is easily increased due to the heat brought to the device housing, and the device housing has a position in contact with the head or other parts of the user, and the temperature increase of the position easily causes poor use experience of the user and even can scald the user.

Disclosure of Invention

The embodiment of the invention discloses a main body device of head-mounted equipment and the head-mounted equipment, which can discharge heat of the head-mounted equipment in time and improve the heat dissipation effect of the main body device of the head-mounted equipment and the head-mounted equipment.

In order to achieve the above object, in a first aspect, the present invention discloses a main body apparatus of a head-mounted device, the main body apparatus including

The air conditioner comprises a first shell, a second shell and a control device, wherein an air outlet is formed in at least one of two ends of the first shell in the length extension direction; and

the host is accommodated in the first shell, at least one air duct is arranged between the host and the first shell, the air duct is communicated with the air outlet, and heat generated by the host is transmitted to the air outlet through the air duct and is discharged.

In a second aspect, the invention further discloses a head-mounted device, which includes a wearing part and the main body apparatus as described in the first aspect, wherein the wearing part is used for connecting the first housing to wear the main body apparatus on the head of a user.

Compared with the prior art, the invention has the beneficial effects that:

according to the main body device of the head-mounted equipment and the head-mounted equipment disclosed by the embodiment of the invention, the air outlet is arranged at least at one end of the first shell of the main body device in the length direction, at least one air channel is formed between the main machine accommodated in the first shell and the first shell, and the air channel can be communicated with the air outlet, so that heat generated by the main machine can be transmitted to the air outlet through the air channel and then is discharged. Adopt this kind of mode, utilize wind channel transferable heat to air outlet to need not to conduct the heat to the casing, avoid heating the casing, improve the problem that the position of casing and user contact is heated and heaies up and influence the user and use experience among the correlation technique, effectively improve user and use experience.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic perspective structure diagram of a main device of a head-mounted device according to an embodiment of the present invention;

fig. 2 is a schematic perspective exploded structure diagram of a main device of a head-mounted device according to an embodiment of the present invention;

fig. 3 is a schematic internal structure diagram of a main device of a head-mounted apparatus according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a first air duct and a second air duct of a main body device of the head-mounted apparatus according to an embodiment of the disclosure;

fig. 5 is a schematic perspective exploded view of a first housing of a main device of a head-mounted apparatus according to an embodiment of the disclosure;

fig. 6 is a schematic perspective structural diagram of a rear shell of a main body device of the head-mounted device disclosed in the first embodiment of the present invention;

fig. 7 is a schematic perspective structural view of a front shell of a main body device of the head-mounted device according to an embodiment of the disclosure;

fig. 8 is a schematic perspective view of a main body of a main device of a head-mounted device according to an embodiment of the present invention;

fig. 9 is a schematic perspective exploded view of a main unit of a main device of a head-mounted device according to an embodiment of the present invention;

fig. 10 is an internal cross-sectional view of a main body of a head-mounted device according to an embodiment of the present invention;

fig. 11 is a schematic perspective view of an opto-mechanical support of a main device of a head-mounted apparatus according to an embodiment of the present invention;

FIG. 12 is a perspective view of FIG. 11 from another perspective;

fig. 13 is a schematic structural diagram of another view angle of the host of the main device of the head-mounted apparatus according to an embodiment of the disclosure;

FIG. 14 is an exploded view of a portion of FIG. 13;

fig. 15 is a schematic perspective view of a control assembly of a main device of a head-mounted apparatus according to an embodiment of the disclosure;

fig. 16 is a schematic perspective view illustrating a heat dissipation module of a main device of a head-mounted device according to an embodiment of the disclosure;

fig. 17 is a schematic perspective exploded view of a heat dissipation module of a main device of a head-mounted device according to an embodiment of the disclosure;

fig. 18 is a schematic perspective exploded view of a heat dissipation module, a control module, and an optical-mechanical support of a main device of a head-mounted apparatus according to an embodiment of the present invention;

fig. 19 is a schematic perspective view of a heat dissipation module, a control module, and an optical-mechanical support of a main device of a head-mounted apparatus according to an embodiment of the present invention;

fig. 20 is a schematic perspective view of a nose pad of a main device of a head-mounted apparatus according to an embodiment of the disclosure;

fig. 21 is a schematic perspective view of a head-mounted device according to a second embodiment of the present invention;

fig. 22 is a schematic perspective exploded view of a head-mounted device according to a second embodiment of the disclosure;

fig. 23 is another schematic structural diagram of the head-mounted device disclosed in the third embodiment of the invention;

fig. 24 is a schematic structural diagram of a headset according to a third embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the present invention, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "center", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate an orientation or positional relationship based on the orientation or positional relationship shown in the drawings. These terms are used primarily to better describe the invention and its embodiments and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meanings of these terms in the present invention can be understood by those skilled in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meanings of the above terms in the present invention can be understood by those of ordinary skill in the art according to specific situations.

Furthermore, the terms "first," "second," and the like, are used primarily to distinguish one device, element, or component from another (the specific nature and configuration may be the same or different), and are not used to indicate or imply the relative importance or number of the indicated devices, elements, or components. "plurality" means two or more unless otherwise specified.

Example one

Referring to fig. 1 to fig. 3, an embodiment of the invention discloses a main device 100 of a head-mounted apparatus, and the main device 100 can be applied to the head-mounted apparatus as a main body of the head-mounted apparatus. The main body apparatus 100 includes a first housing 1 and a main body 2. Considering that the main body device 100 is a main body part of the head-mounted apparatus, the main body device 100 may be an elongated housing, and the first housing 1 may be an elongated housing, and at least one of two ends of the elongated housing in the extending direction of the length of the elongated housing may be provided with the air outlet 10. The main unit 2 is accommodated in the first casing 1, at least one air duct 11 is arranged between the main unit 2 and the first casing 1, and the at least one air duct 11 is communicated with the air outlet 10, so that heat generated by the main unit 2 can be transmitted to the air outlet 10 through the air duct 11 and exhausted.

Like this, when main part device 100 is applied to head-mounted apparatus, utilize the cooperation of wind channel 11 and air outlet 10, can give off the heat to the outside of first casing 1 fast, replaced adopting in the correlation technique to set up the mode that the fin conducts the heat to the casing and gives off at main part device, improved the radiating efficiency on the one hand, on the other hand also can avoid the heat gathering at the casing and lead to the casing temperature to rise the problem that influences the customer and wear experience.

It is understood that the above mentioned head-mounted device means to transmit optical signals to human glasses through various head display devices, so that different effects such as Virtual Reality (VR), Augmented Reality (AR), or Mixed Reality (MR) can be realized. Illustratively, the head-mounted device may be AR glasses, VR glasses, MR glasses, or the like.

Therefore, the main device 100 of the present embodiment may be a device for arranging an optical component, a display device, a functional device (such as a camera, a speaker, or a microphone), and a control component (such as a circuit board) in the head-mounted apparatus. The main body device 100 can be matched with the wearing part, so that the main body device 100 can be worn on the head of a human body.

It is understood that the air duct 11 formed between the first casing 1 and the main body 2 can be formed by:

in a first alternative embodiment, when the main unit 2 is disposed in the first casing 1, a gap is formed between the outer periphery of the main unit 2 and the inner wall surface of the first casing 1, and the gap may be formed as the air duct 11.

In a second alternative embodiment, a gap is provided in the main body 2 itself, for example, a gap may be formed between components included in the main body 2 itself, and the air duct 11 may be formed by communicating the gap with the air outlet 10.

In a third alternative embodiment, a gap may be provided between the inner wall surface of the first casing 1 and the outer periphery of the main unit 2, and at the same time, the main unit 2 itself is provided with a gap, so that the gaps jointly form the air duct 11.

In some embodiments, the first casing 1 is provided with the air outlets 10 at both ends along the length direction thereof, and the air outlets 10 may include a first air outlet 10a at one end of the first casing 1 and a second air outlet 10b at the other end of the first casing 1. The first air outlet 10a and the second air outlet 10b are respectively arranged at two ends of the first shell 1 in the length direction, and the air duct 11 can disperse heat to the first air outlet 10a and the second air outlet 10b to respectively discharge air, so that heat dissipation can be accelerated, and the heat dissipation effect of the main body device 100 is improved.

Optionally, the air outlet 10 may be the whole air outlet 10 or the air outlet 10 formed by a plurality of air outlets. For example, a plurality of strip-shaped air outlets may be disposed on the first casing 1, and the air outlets 10 are formed by the plurality of strip-shaped air outlets.

In some embodiments, in order to rapidly transmit heat to the air outlet 10 and improve heat dissipation, the first housing 1 may further include an air inlet 12, the air inlet 12 may be located between two ends of the first housing 1, and the air duct 11 may be in communication with the air inlet 12 and located between the air inlet 12 and the air outlet 10. Specifically, the air inlet 12 may be disposed at a middle position of the first housing 1, such that the air outlet 10 and the air inlet 12 are spaced far apart, and thus the air duct 11 may pass through a longer area, and a heat source area passing through the air duct is larger, which is beneficial to taking more heat away from the air outlet 10. In addition, the air inlet 12 is disposed at the middle position of the first housing 1, when the first air outlet 10a and the second air outlet 10b are respectively disposed at two ends of the first housing 1, the air (or air) entering from the air inlet 12 can be divided into two paths, and the two paths carry heat to be respectively discharged to the first air outlet 10a and the second air outlet 10b along the channel, so as to avoid the situation that the heat dissipation effect is affected due to the hot air discharged from the first air outlet 10a and the second air outlet 10b entering again through the air inlet 12. It is understood that, in other embodiments, the inlet 12 may be disposed at a non-central position of the first casing 1, for example, the inlet 12 may be disposed closer to the first outlet 10a or the second outlet 10 b.

Alternatively, the air inlet 12 may be a whole air inlet 12 or a plurality of air inlet holes may be formed on the first casing 1, for example, a plurality of air inlet holes may be formed on the first casing 1, and the plurality of air inlet holes may be shaped as strip-shaped holes, circular holes, or shaped as strip-shaped holes and circular holes. The plurality of air inlet holes may be spaced apart and arranged along the length direction of the first housing 1, thereby increasing a communication portion with the passage and increasing an air inlet amount to improve a heat dissipation effect.

In some embodiments, as shown in fig. 4 to 6, the main body device 100 further includes a lens 3, the first casing 1 includes a first frame portion 13 and a covering portion 14, the first frame portion 13 is used for mounting the lens 3, one end of the covering portion 14 is connected to the first frame portion 13, the covering portion 14 is used for enclosing with the first frame portion 13 to form an accommodating space 13a for accommodating the host 2, and the air inlet 12 and the air outlet 10 can be disposed on the covering portion 14. In particular, the housing portion 14 may be in the form of an elongated shell, which may enclose the side of the first frame portion 13 facing away from the side for mounting the lens 3, thereby avoiding blocking the lens 3 mounted on the first frame portion 13.

Further, the first housing 1 further includes a frame portion 15, one end of the frame portion 15 is connected to one end of the covering portion 14 away from the first frame portion 13, the other end of the frame portion 15 is mounted corresponding to the first frame portion 13, and the frame portion 15 is used for holding at least part of the main frame 2. Thus, the frame portion 15, the covering portion 14, and the first frame portion 13 together enclose the accommodating space 13a, so that the main unit 2 can be accommodated in the accommodating space 13a easily.

Specifically, the frame part 15 and the cover part 14 may be an integral structure and constitute the rear case 1a of the first housing 1. In other words, the frame portion 15 and the cover portion 14 can be molded integrally, so that the frame portion 15 and the cover portion 14 serve as the rear case 1a of the first housing 1. The assembly of the components of the main apparatus 100 can be simplified by integrally molding the frame portion 15 and the cover portion 14. It is understood that in other embodiments, the frame portion 15 and the cover portion 14 may be a split structure, and they may be assembled together by bonding, screwing, snapping, or welding to form the rear shell 1a of the first housing 1.

As shown in fig. 5 to 7, in some embodiments, the first housing 1 further includes an adapter portion 16, one end of the adapter portion 16 is connected to the first frame portion 13, and the other end of the adapter portion 16 is used for connecting a wearing portion for wearing the main body device 100 on the head of the user. Specifically, the adapter portion 16 is connected to one end of the first frame portion 13 in its own lengthwise direction, thereby facilitating connection of the adapter portion 16 with the wearing portion. Considering that the wearing portion is worn on the head of the user, the number of the adapter portions 16 may be two, and the two adapter portions 16 are respectively connected to both ends of the first frame portion 13.

Alternatively, the adaptor portion 16 and the first frame portion 13 may be an integral structure and constitute the front case 1b of the first housing 1. Providing the adapter portion 16 as an integral structure with the first frame portion 13 can simplify component assembly of the main body apparatus 100. It is understood that in other embodiments, the adaptor portion 16 and the first frame portion 13 may be a split structure, and the two may be assembled together by bonding, screwing, snapping, or welding to form the front shell 1b of the first housing 1.

In some embodiments, the junction between the adaptor portion 16 and the first frame portion 13 defines a vent 13b, and the outlet air of the outlet 10 can be exhausted through the vent 13 b. Specifically, the adapter portion 16 includes a first portion 161 and a second portion 162 connected to each other, the first portion 161 being used to connect the first frame portion 13, and the second portion 162 being used to rotatably connect the wearing portion. The junction of the first portion 161 and the first frame portion 13 may define a vent 13b, and the second portion 162 and the wearing portion may be rotatably coupled to facilitate storage of the wearing portion.

Alternatively, the adaptor portion 16 may be a housing structure having a hollow portion, and both ends of the hollow portion of the adaptor portion 16 may be connected to the first frame portion 13, so that the vent 13b can be formed between the first frame portion 13 and the adaptor portion 16, and the vent 13b is an opening of the hollow portion, so that heat exhausted from the air outlet 10 on the covering portion 14 can be further exhausted through the vent 13b between the first frame portion 13 and the adaptor portion 16, thereby preventing the heat from being collected on the adaptor portion 16, and improving the heat dissipation effect.

In some embodiments, the first housing 1 further includes an extending end 17, one end of the extending end 17 can be connected to the housing portion 14, and the other end of the extending end 17 is used for being fixed to the second portion 162 of the adapting portion 16, so as to connect the housing portion 14 to the adapting portion 16 and the first frame portion 13. Specifically, the two ends of the covering portion 14 in the length direction are connected to extension ends 17, and the extension ends 17 can extend into the ventilation openings 13b where the first frame portion 13 and the adapter portion 16 are connected, so that the connecting positions of the covering portion 14 and the adapter portion 16 can be hidden, and the appearance decoration effect of the main body device 100 is improved.

Optionally, the extending end 17 extends into the ventilation opening 13b where the first frame part 13 and the adaptor part 16 are connected and is connected with the adaptor part 16 through a screw connection manner, so that the screw connected with the adaptor part 16 can be hidden, and the appearance decoration effect of the main body device 100 is improved.

Further, as can be seen from the foregoing, the air outlets 10 are disposed at both ends of the covering portion 14, when the extending end 17 extends into the ventilation opening 13b at the connection position of the first frame portion 13 and the adapter portion 16, the air outlets 10 can be disposed toward the adapter portion 16, so that the positions of the air outlets 10 can be hidden by the adapter portion 16, on one hand, the user cannot easily see the air outlets 10 visually, and the user also cannot easily touch the air outlets 10, so that when the user uses the head-mounted device, the relevant portions (for example, the head, the hands, etc.) cannot sense the high-temperature hot air discharged from the air outlets 10, thereby achieving the hot air isolation of the air outlets 10. On the other hand, the air outlet 10 can be hidden, and the integrity and the aesthetic property of the appearance shape of the whole machine of the head-wearing equipment are very favorable.

In some embodiments, at least a portion of the surface 163 of the adapter 16 is opposite to the outlet 10, and the at least a portion of the surface 163 can be used to guide the outlet air of the outlet 10. In particular, the at least part of the surface 163 may be a surface of the adaptor portion 16 facing the first frame portion 13, and the surface may be opposite to the air outlet 10, so that hot air (e.g. heat or hot air) coming out from the air outlet 10 may form a swirling turbulent air mass through the surface of the adaptor portion 16, thereby reducing the discharge speed of the hot air flow at this point and avoiding a large heat accumulation at the hollow opening of the adaptor portion 16.

Further, at least a part of the surface 163 of the adapter 16 encloses a concave portion that is concave toward a side away from the outlet 10, and the concave portion can be used for guiding the outlet air of the outlet 10. In particular, the recess may have at least part of the surface 163 as described above. By adopting the way that at least part of the surface of the adapter part 16 is surrounded by the sunken part which is sunken towards the direction far away from the air outlet 10, the hot air flow exhausted from the air outlet 10 can form a rotary turbulent air mass, thereby greatly reducing the exhausting speed of the hot air flow.

In some embodiments, the first housing 1 further includes a protective cover 18, the protective cover 18 is disposed around the first frame portion 13 and the adaptor portion 16, and the protective cover 18 is further disposed on the covering portion 14 to connect at least a portion of the first frame portion 13. Specifically, the protective cover 18 can serve as a decorative protective cover, which can decorate the main device 100, on the other hand, the protective cover 18 can cover the connecting position of the first frame part 13 and the adapter part 16, hide the rotating shaft or the screw or the like connected with the first frame part 13 and the adapter part 16, and hide electric connectors (such as a flexible circuit board, an electric wire or the like connected with the wearing part) on the first frame part 13 and the adapter part 16.

Further, the protective cover 18 may be made of a heat conductive material, such as a metal material, so that the protective cover 18 can also perform auxiliary heat dissipation generated by the host computer 2 to the outside. Illustratively, the protective cover 18 may be made of a material such as an aluminum alloy, so as to have a good appearance decoration effect and effectively assist in heat dissipation.

Referring again to fig. 3 to 6, in some embodiments, the covering portion 14 may include a cover portion 14a connected to the first frame portion 13 and side portions 14b connected to both ends of the cover portion 14a, the air outlet 10 may be disposed on the side portions 14b, and the air inlet 12 may be disposed on the cover portion 14 a. Specifically, the side plate portions 14b at the two ends of the cover plate portion 14a may extend obliquely downward from the two ends of the cover plate portion 14a, and the extension end 17 may extend outward from the joint of the cover plate portion 14a and the side plate portion 14b, so that when the extension end 17 extends into the joint of the adaptor portion 16 and the first frame portion 13, the extension end 17 may cover the side plate portions 14b, so that the air outlet 10 disposed on the side plate portions 14b is formed as the hidden air outlet 10.

Further, cover plate portion 14a may include a first cover plate portion 141 connecting first frame portion 13 and a second cover plate portion 142 connecting first cover plate portion 141, and first cover plate portion 141 and second cover plate portion 142 may be connected at an angle to form cover plate portion 14a in an approximately L-shape. The first cover portion 141 may be disposed substantially horizontally, the second cover portion 142 is substantially perpendicular to the first cover portion 141, and the air duct 11 may include a first air duct 11a (shown by a dotted arrow in fig. 4, which also indicates an air flow direction in the first air duct 11 a) between the main unit 2 and the first cover portion 141 and a second air duct 11b (shown by a dotted arrow in fig. 4, which also indicates an air flow direction in the second air duct 11 b) between the main unit 2 and the second cover portion 142. Like this, through setting up a plurality of wind channels 11, and a plurality of wind channels 11 are located different positions respectively, can transmit the heat of different positions to air outlet 10 through a plurality of wind channels 11 and discharge to can improve the radiating effect.

In order to accurately control the cooling effect generated by the air flow passing through the first air duct 11a and the second air duct 11b, the first air duct 11a and the second air duct 11b may be sealed respectively, so that the first air duct 11a and the second air duct 11b are not communicated at least partially. The first air duct 11a may be sealed in the following manner:

in an alternative embodiment, the main unit 2 and the first cover portion 141 tightly abut against each other to seal the first air duct 11a, so that the cool air entering the first air duct 11a through the first air inlet 12 and the hot air flow in the first air duct 11a can be prevented from being dispersed between the main unit 2 and the second cover portion 142.

In another alternative embodiment, a first sealing member (not shown) may be disposed between the main body 2 and the first cover plate portion 141 to seal the first air duct 11 a. The first sealing member may include one or more of foam, silicone, or adhesive backing, such that the first air duct 11a is sealed by the first sealing member.

In yet another alternative embodiment, the main body 2 is tightly abutted against the first cover plate portion 141, and a first sealing member may be further disposed between the main body 2 and the first cover plate portion 141 to seal the first air duct 11 a.

The second air duct 11b may be sealed in the following manner:

in an alternative embodiment, the host 2 and one end of the second cover portion 142 away from the first cover portion 141 tightly abut against each other to seal the second air duct 11b, so that the cold air entering from the second air inlet 12 and the air flow in the second air duct 11b can be prevented from being transmitted between the first cover portion 141 and the host 2, and the heat can be prevented from being dispersed between the host 2 and the first cover portion 141.

In another alternative embodiment, a first sealing member may be disposed between the main body 2 and an end of the second cover plate portion 142 away from the first cover plate portion 141 to seal the second air duct 11 b. The first sealing member may include one or more of foam, silicone, or adhesive backing, so that the sealing of the second air duct 11b is achieved by the first sealing member.

In yet another alternative embodiment, the main unit 2 and the second cover plate 142 are tightly abutted, and a first sealing member may be further disposed between the main unit 2 and the second cover plate 142 to seal the second air duct 11 b.

The first air duct 11a and the second air duct 11b are respectively sealed, so that the first air duct 11a and the second air duct 11b are at least partially independent, different positions of the first air duct 11a and the second air duct 11b can be utilized, a heat source on the main machine 2 can be arranged corresponding to different positions of the air ducts 11 according to the arrangement, and the cooling effect generated when air flows pass through different air ducts 11 can be accurately controlled.

In some embodiments, the first wind tunnel 11a and the second wind tunnel 11b may have a fusion area 111 (see fig. 3), and the wind (or the air flow (mixture of wind and heat)) of the first wind tunnel 11a and the second wind tunnel 11b may be fused at the fusion area 111. In other words, the first air duct 11a and the second air duct 11b are partially independent and then are merged at the merging area 111, so that the shape and size of each air duct 11 can be independently designed according to different heat sources, and further, the cooling effect generated when different air flows pass through different air ducts 11 can be controlled.

In an alternative embodiment, the merging area 111 may be disposed adjacent to the air inlet 12, so that the first air duct 11a and the second air duct 11b may share the air inlet 12, and the air from the air inlet 12 may flow to the first air duct 11a and the second air duct 11b through the merging area 111, respectively. In other words, the first air duct 11a and the second air duct 11b are integrated at the front section of the intake air and are independent at the rear section, so that the shape and size of each air duct 11 can be designed independently, and the wind resistance, wind pressure, ventilation volume and the like of each area can be changed, thereby accurately controlling the cooling degree of each area in the first housing 1 and each heat source of the host 2.

In another alternative embodiment, the merging area 111 may be disposed adjacent to the air outlet 10, so that the first air duct 11a and the second air duct 11b may share the air outlet 10, and the air (or air flow) from the first air duct 11a and the second air duct 11b may flow to the air outlet 10 through the merging area 111. Like this, the anterior segment mutually independent of first wind channel 11a and second wind channel 11b air inlet, and the back end is close to the air-out position and then fuses, and the form, the size of each wind channel 11 of independent design of equally being convenient for to can effectively change wind resistance, wind pressure, air volume etc. in each region.

It is understood that in other embodiments, two or more of the individual air paths 11 may be merged in advance and then merged with other air paths 11 again. For example, at least one of the first wind tunnel 11a and the second wind tunnel 11b may include a first sub-channel corresponding to the wind inlet 12 and a second sub-tunnel 11 corresponding to the wind outlet 10, and the fusion zone 111 may be located between the first sub-channel and the second sub-channel. In this way, independent design of each channel may be facilitated.

It is understood that the merging sequence and merging position of the two or more sub-channels in each independent air duct 11 can be adjusted according to actual conditions, for example, the merging sequence and merging position can be adjusted according to the arrangement condition of the heat source positions of the main unit 2 in the first housing 1, which is not limited in this embodiment.

In addition, in other embodiments, the independent air ducts 11 may be merged first, for example, they may be merged near the air inlet 12, and then the air ducts 11 may be separated again according to the arrangement of the heat source positions of the host 2 in the first housing 1, so as to conduct the heat to other areas, thereby averaging the overall temperature of the main device 100.

Of course, in other embodiments, the independent air ducts 11 may be merged first, and then the air ducts 11 are separated again according to the arrangement of the heat source position of the host machine 2 in the first housing 1, so that the air volume at one of the air inlets 12 is split into a plurality of air ducts, and then the air ducts are divided to pass through the heat source area needing cooling, and then merged at the air outlet 10.

Optionally, in order to further improve the heat dissipation effect, the air inlets 12 may be multiple, and are respectively the first air inlet 121 and the second air inlet 122, the first air inlet 121 may be disposed on the first cover plate portion 141, and the second air inlet 122 may be disposed on the second cover plate portion 142, so that the first air inlet 121 may be communicated with the first air duct 11a, and the second air inlet 122 may be communicated with the second air duct 11b, and thus, different air inlets 12 are respectively disposed corresponding to different air ducts 11, so that the heat dissipation speed may be increased, and the heat dissipation effect may be improved.

In practical applications, the first air inlet 121 may be disposed at a middle position of the first cover portion 141, the second air inlet 122 may be disposed at a middle position of the second cover portion 142, and one or more of the first air inlet 121 and the second air inlet 122 may be provided.

In this arrangement, the external air may enter the independent air ducts 11 through the air inlets 12, and then the air ducts 11 are merged according to the arrangement of the heat source positions of the host 2 in the first housing 1, and then separated into the independent air ducts 11, and finally discharged outside the host 2 through the air outlets 10.

The arrangement of the heat source of the main unit 2 according to the present embodiment will be described in detail below with reference to the drawings, so as to match the heat source of the main unit 2 with the channel.

Referring to fig. 8 to 10, in some embodiments, the main body 2 may include an optical mechanical element 20 and a control element 22, and heat generated by at least one of the optical mechanical element 20 and the control element 22 may be transmitted to the air outlet 10 through the air duct 11 to be exhausted. That is, the optical-mechanical assembly 20 and/or the control assembly 22 can be used as a heat source, and heat generated during the operation process can be transmitted to the air outlet 10 through the air duct 11, so that rapid heat dissipation can be realized, and the situation that the normal operation of the optical-mechanical assembly 20 and/or the control assembly 22 is affected due to heat accumulation is avoided.

In some embodiments, the opto-mechanical assembly 20 includes an opto-mechanical light source 20a, an optical assembly 20b, and an opto-mechanical support 20c, both the opto-mechanical light source 20a and the optical assembly 20b being mountable on the opto-mechanical support 20 c. Specifically, the optical engine light source 20a is mainly used for emitting light, and the optical assembly 20b is used for transmitting the light emitted by the optical engine light source 20a to the eyes of the user. It is understood that the light engine light source 20a may alternatively be an OLED light source. The channel can at least partially pass through the area where the optical machine light source 20a is located, so that heat generated by the optical machine light source 20a can be timely dissipated to the air outlet 10.

Further, in order to be able to be disposed corresponding to the human eye, the number of the optical engine light sources 20a may include two, and then the optical engine bracket 20c is a strip-shaped bracket, and the length direction of the optical engine bracket 20c may be along the length direction of the first housing 1, and the length of the optical engine bracket 20c may be approximately matched with the length of the first housing 1, that is, slightly shorter than the length of the first housing 1, so that the optical engine bracket 20c may be adapted to the inner space of the first housing 1, and at the same time, the inner space of the first housing 1 may also be utilized, so as to facilitate the arrangement of the devices. Specifically, the optical engine bracket 20c may include two supporting portions 201 and a connecting portion 202 connected between the two supporting portions 201, the two supporting portions 201 are symmetrically disposed, the two supporting portions 201 may be respectively configured to support the two optical engine light sources 20a, the number of the optical assemblies 20b corresponds to the number of the optical engine light sources 20a and may be two sets, so as to separate and correspondingly dispose the two optical engine light sources 20a, and the two sets of optical assemblies 20b may be respectively disposed corresponding to human eyes, so as to respectively transmit light of the two optical engine light sources 20a to the two human eyes.

As shown in fig. 11 to 12, the supporting portion 201 may further include a sidewall structure 203 having a hollow opening, the optical engine light source 20a may be disposed on one side of the opening of the sidewall structure 203, and at least a portion of the optical assembly 20b may be disposed on the opening of the sidewall structure 203. Specifically, the sidewall structure 203 may be formed by protruding a boss on the supporting portion 201, the sidewall structure 203 has an upper opening and a lower opening, the upper surface 203a of the sidewall structure 203 may be provided with the optical engine light source 20a, the optical element 20b is disposed in the hollow opening of the sidewall structure 203, the light emitted by the optical engine light source 20a is transmitted to the optical element 20b through the opening of the upper surface 203a of the sidewall structure 203, and the optical element 20b transmits the light to the human eye through the lower opening of the sidewall structure 203.

Optionally, the light engine light source 20a is detachably disposed on the upper surface 203a of the sidewall structure 203, and may be fixed on the upper surface 203a of the sidewall structure 203 by a screw connection, a snap connection, or a magnetic attraction. For example, a plurality of protruding studs 203b may be disposed on the upper surface 203a of the sidewall structure 203, and then the light engine light source 20a may be fixed on the studs 203b by screws or bolts, thereby fixing the light engine light source 20a on the upper surface 203a of the sidewall structure 203.

In some embodiments, the optical assembly 20b may include a lens group 204, a first optical unit 205 and a second optical unit 206, the lens group 204 may be mounted on an inner surface of the sidewall structure 203, the first optical unit 205 may be located on a side of the sidewall structure 203 away from the optical engine light source 20a, the second optical unit 206 is disposed corresponding to the first optical unit 205, and the first optical unit 205 is configured to guide light rays emitted by the optical engine light source 20a received through the lens group 204 onto the second optical unit 206. Specifically, the lens group 204 may include two or more lenses, the lens group 204 may be disposed in the opening of the sidewall structure 203, and the lens group 204 is close to the opening of the upper surface 203a of the sidewall structure 203, and the lens group 204 is configured to receive light emitted by the optical light source and transmit the light to the first optical unit 205. The first optical unit 205 may be disposed at the lower opening of the sidewall structure 203 and covers the lower opening of the sidewall structure 203, and the first optical unit 205 may be a beam splitter, which may be disposed obliquely with respect to the optical axis of the lens assembly 204, so as to reflect the light onto the second optical unit 206.

Further, one end of the beam splitter adjacent to the sidewall structure 203 is located on a side of the sidewall structure 203 away from the second optical unit 206, and the second optical unit 206 is located on a second side of the sidewall structure 203. Specifically, the second optical unit 206 may be disposed adjacent to the lens 3 of the body device 100 so that light can be transmitted into the human eye.

Further, the opto-mechanical bracket 20c further includes two extending portions 207 disposed at two ends of the sidewall structure 203 and disposed oppositely, and the two extending portions 207 are used for fixing the corresponding first optical unit 205 and the second optical unit 206. Specifically, two extending portions 207 are disposed at two ends of the lower portion of the sidewall structure 203, the two extending portions 207 and the lower portion of the sidewall structure 203 enclose to form an accommodating space 203c, the first optical unit 205 and the second optical unit 206 can be disposed in the accommodating space 203c, and two ends of the first optical unit 205 and two ends of the second optical unit 206 are respectively connected to the two extending portions 207.

Alternatively, the extension portion 207 may be a thin plate structure protruding from the lower portion of the sidewall structure 203, and in practice, two thin plates may protrude from the lower portion of the sidewall structure 203, and in order to facilitate the first optical unit 205 to be disposed obliquely with respect to the optical axis of the lens group 204, the extension portion 207 may be disposed as an approximately triangular rib.

In addition, in order to prevent light leakage at the connection between the two ends of the first optical unit 205 and the second optical unit 206 and the extending portion 207, a light shielding material may be disposed on the two surfaces of the two extending portions 207 facing each other, for example, ink may be applied on the surfaces. Alternatively, the extension 207 may be integrally provided as a light shielding material.

In some embodiments, in order to fix the optical engine bracket 20c in the first casing 1, the optical engine bracket 20c further includes two locking ends 208, the two locking ends 208 may be respectively located at two ends of the optical engine bracket 20c, each of the locking ends 208 is respectively connected to the corresponding extension portion 207, and the locking ends 208 may be used to lock with the first casing 1, so as to fix the optical engine bracket 20c in the first casing 1. Specifically, the locking end 208 may be protruded from the outer surface of the extension 207 near the end of the optical engine bracket 20c, and a locking screw hole may be provided on the locking end 208, through which a fastener (e.g., a screw or a bolt) may pass to be fixed to the first housing 1. It is understood that in other embodiments, the locking end 208 can be fixed to the first housing 1 by adhesion, and the optical-mechanical support 20c can be fixed in the first housing 1.

In some embodiments, the opto-mechanical mount 20c further includes a fixing mount 209, the fixing mount 209 may be connected to at least one of the supporting portion 201 or the connecting portion 202, the main unit 2 may further include a camera assembly 24, and the camera assembly 24 may be fixed on the fixing mount 209. Specifically, the fixing bracket 209 may be disposed on the connecting portion 202, specifically, may be disposed on one side edge of the connecting portion 202, and the camera module 24 may be disposed on the fixing bracket 209, so that the camera module 24 is disposed in a region near the middle of the opto-mechanical bracket 20c, and the opto-mechanical module 20 is disposed in a region near both ends of the opto-mechanical bracket 20c, and since the camera module 24 also generates heat during operation, the camera module 24 may also serve as a heat source of the host computer 2. The camera assembly 24 is arranged on the fixing support 209 of the connecting part 202, and the optical mechanical assembly 20 is arranged at two ends of the optical mechanical support 20c, so that heat sources of the host machine 2 can be distributed at different positions of the whole machine, and the problem that the host machine 2 is in operation failure due to over-concentrated heat is avoided.

It will be appreciated that in order to dissipate the heat generated by the camera assembly 24 and opto-mechanical assembly 20 in a timely manner, the passage should pass at least partially through the area where the camera assembly 24 and opto-mechanical assembly 20 are located.

Further, the camera assembly 24 may include one or more.

In an alternative embodiment, the fixing bracket 209 may include a first fixing bracket 209a connected to the connecting portion 202 and located between the two supporting portions 201, and the camera assembly 24 may include a first camera assembly 241, and the first camera assembly 241 may be mounted on the first fixing bracket 209 a. Optionally, the first camera assembly 241 may include one or more cameras, which may provide the same or different functionality. For example, taking the example that the first camera assembly 241 includes two cameras, of the two cameras, both cameras may provide the same function, e.g., both may implement the modeling function, or may provide different functions, e.g., one camera provides the modeling function and the other provides the shooting function.

In another alternative embodiment, the camera module 24 may further include a second camera module 242, and the fixing bracket 209 further includes a second fixing bracket 209b disposed on a side of the supporting portion 201 away from the connecting portion 202, that is, the second fixing bracket 209b is disposed at a position of the supporting portion 201 near its end, and the second camera module 242 may be mounted on the second fixing bracket 209 b. The second camera module 242 may also include one or more second camera modules, for example, the number of the second camera modules 242 may be two, the number of the second fixing brackets 209b may be two, the two second fixing brackets 209b are respectively disposed on the sides of the two supporting portions 201 far away from the connecting portion 202, and the two second camera modules 242 are respectively mounted on the two second fixing brackets 209 b. The second camera assembly 242 may likewise include one or more cameras, and the multiple cameras of the second camera assembly 242 may provide the same or different functions. For example, the second camera component 242 may include two cameras, which may both be fisheye lenses, and since the second camera component 242 is disposed near the end position of the supporting portion 201, it may acquire environmental information near the end position of the first housing 1 for processing.

In yet another alternative embodiment, the camera module 24 may include both the first camera module 241 and the second camera module 242, the fixing bracket 209 may include a first fixing bracket 209a disposed on the connecting portion 202 and a second fixing bracket 209b disposed on a side of the supporting portion 201 away from the connecting portion 202, the first camera module 241 may be mounted on the first fixing bracket 209a, and the second camera module 242 may be mounted on the second fixing bracket 209 b. The imaging unit 24 includes both the first imaging unit 241 and the second imaging unit 242, and thus different functions can be realized, thereby improving the functional diversity of the main apparatus 100. In addition, the first camera module 241 is arranged in the middle of the optical machine support 20c, and the second camera module 242 is arranged at the end of the optical machine support 20c, so that the camera modules 24 can be separately arranged, and the situation that the operation is possibly affected due to too concentrated heat when the first camera module 241 and the second camera module 242 are arranged together and operate at the same time is avoided. Moreover, since the air outlet 10 is disposed at the end of the first casing 1, the second camera component 242 can be disposed at the end of the first casing to quickly guide heat out through the air outlet 10, thereby improving heat dissipation effect.

In some embodiments, as shown in fig. 13 to 14, in order to guide the wind in the wind channel 11 to the wind outlet 10 for discharging, and concentrate the heat generated by the host 2 to the wind outlet 10, the host 2 may further include a heat dissipation fan 26, and the heat dissipation fan 26 may be located in the wind channel 11. Specifically, as can be seen from the foregoing, the two optical engine light sources 20a are respectively disposed at two ends of the optical engine support 20c, and the two air outlets 10 include two air outlets respectively disposed at two ends of the covering portion 14, so that the number of the heat dissipation fans 26 can be two, and the two heat dissipation fans 26 can be respectively mounted at two ends of the optical engine support 20 c. The two heat dissipation fans 26 are arranged to accelerate the air flow in the air duct 11 to be guided to the air outlet 10 for being discharged, thereby improving the heat dissipation efficiency.

Further, the heat dissipation fan 26 may be disposed adjacent to the air outlet 10, so as to guide the air in the air duct 11 to the air outlet 10 for being exhausted. Specifically, the heat dissipation fan 26 may be a suction fan, which can form a negative pressure at the air outlet 10, so as to draw the air flow in the air duct 11 and the heat generated by the host 2 to the heat dissipation fan 26, so as to be concentrated at the air outlet 10 for being discharged. In other words, since the heat dissipation fan 26 of the present embodiment is a suction fan, when the external air enters the first housing 1 from the air inlet 12, the external air is sucked by the negative pressure of the heat dissipation fan 26, passes through the air duct 11 from the components (such as the optical mechanical component 20 and the control component 22) of the main machine 2, and transmits the heat generated by the operation of the optical mechanical component 20 and the control component 22 to the heat dissipation fan 26, so as to be exhausted through the air outlet 10.

In some embodiments, a side of the supporting portion 201 facing away from the connecting portion 202 and the first casing 1 form a circulation space 201a, and the air duct 11 may include the circulation space 201a, so that the heat dissipation fan 26 may be located in the circulation space 201a or disposed adjacent to the circulation space 201 a. Specifically, the supporting portion 201 may further include a connecting plate 201b connected to a side of the sidewall structure 203 far from the connecting portion 202, and the connecting plate 201b, an outer surface of the sidewall structure 203 and the first housing 1 enclose the flow space 201 a. In this way, by the arrangement of the connection plate 201b, the circulation space 201a is formed at the connection plate 201b, and the air flows of the channels can be merged at the circulation space, so that the air is sucked by the heat dissipation fan 26 and guided to the air outlet 10 to be discharged, thereby improving the heat dissipation effect.

In practical applications, the heat dissipation fan 26 can be disposed on a side of the supporting portion 201 away from the connecting portion 202, an air outlet side 26b of the heat dissipation fan 26 is opposite to the air outlet 10, and an air inlet side 26a of the heat dissipation fan 26 can be disposed toward the supporting portion 201. Specifically, the heat dissipation fan 26 may be disposed on a side of the sidewall structure 203 away from the connection portion 202, and the heat dissipation fan 26 is disposed vertically. In this case, the air intake side 26a of the radiator fan 26 may be opposed to the connection plate 201 b. In this way, the heat dissipation fan 26 can be disposed in the space at the end of the optical mount 20c, so that the overall structure of the main unit 2 is more compact. It is understood that in other embodiments, the heat dissipating fan 26 may be disposed transversely, i.e. the heat dissipating fan 26 may be disposed on the side of the connecting plate 201b away from the sidewall structure 203, and in this case, the air inlet side 26a of the heat dissipating fan 26 may be opposite to the sidewall structure 203.

In some embodiments, in order to fix the heat dissipation fan 26 on the optical engine support 20c, a protruding portion 201c is disposed on a side of the supporting portion 201 away from the connecting portion 202, a step structure is formed between the protruding portion 201c and the supporting portion 201, so that at least a portion of the heat dissipation fan 26 can be disposed on and supported by the step structure, and the air outlet 10 is located on a side of the heat dissipation fan 26 away from the protruding portion 201 c. Specifically, the protrusion 201c may be disposed on a side of the connection plate 201b away from the sidewall structure 203, and the protrusion 201c may form a step structure with a side of the connection plate 201b, so as to support at least a portion of the heat dissipation fan 26.

In some embodiments, in order to further fix the heat dissipation fan 26, the main body 2 may further include an auxiliary bracket 28, the auxiliary bracket 28 is disposed on the supporting portion 201 and located in the circulation space 201a, and the heat dissipation bracket is located on a side of the auxiliary bracket 28 and the supporting portion 201 away from the connecting portion 202. Specifically, the auxiliary bracket 28 may be disposed on the connecting plate 201b, so that the auxiliary bracket 28 and the protrusion 201c together form a supporting structure for supporting the heat dissipation fan 26, and the heat dissipation fan 26 is fixed on the optical machine support 20 c.

Alternatively, the auxiliary bracket 28 may be fixed to the connecting plate 201b by screws, or may be adhered, clamped, welded, or the like. For the convenience of installation, the auxiliary bracket 28 may be fixed to the connection plate 201b by screws.

It is understood that in other embodiments, the auxiliary bracket 28 may be formed as an integral structure with the connecting plate 201b, and thus the auxiliary bracket 28 and the protrusion 201c may also be formed as an integral structure, which may reduce the assembly process of components.

Further, the auxiliary bracket 28 includes a circulating part 28a and a guide part 28b connected to the circulating part 28a, the circulating part 28a may be located between the guide part 28b and the support part 201, the circulating part 28a may have an air inlet hole 281, the guide part 28b may have an air outlet hole 282, and the air entering the circulating space 201a may sequentially enter the heat dissipation fan 26 through the air inlet hole 281, the space between the guide part 28b and the support part 201, and the air outlet hole 282 and then be guided to the air outlet 10 through the heat dissipation fan 26. In other words, at the circulating part 28a and the guiding part 28b of the auxiliary bracket 28, a circulating channel of the airflow can be formed through the air inlet hole 281, the space between the guiding part 28b and the supporting part 201, and the air outlet hole 282, so that the airflow in the channel can be conveniently and rapidly circulated to the circulating channel and sucked into the heat dissipation fan 26, thereby being guided to the air outlet 10 by the heat dissipation fan 26.

In some embodiments, since the heat dissipation fan 26 is a suction fan, in order to form a negative pressure at the heat dissipation fan 26 to rapidly draw the airflow in the channel to the heat dissipation fan, each connection between the heat dissipation fan 26 and the supporting portion 201 needs to be sealed to form the negative pressure.

In an alternative embodiment, a second sealing element (not shown) can be provided on at least one of the side of the radiator fan 26 facing away from its own air inlet side 26a and the side of the radiator fan 26 facing away from its own air outlet side 26b for sealing the air duct 11. Specifically, the second sealing element may be disposed on the side of the heat dissipation fan 26 away from the air inlet side 26a and the side of the heat dissipation fan 26 away from the air outlet side 26b, so as to prevent the air flow in the air duct 11 from being dissipated through these positions and affecting the air guiding performance of the heat dissipation fan 26. Illustratively, the second seal may comprise one or more of a backing adhesive, foam, silicone.

In another alternative embodiment, a third sealing member 283 may be further disposed on the surface of the guiding portion 28b away from the heat dissipation fan 26 for sealing the air duct 11. Illustratively, the third seal 283 may also be one or more of a back adhesive, foam, or silicone.

In a further alternative embodiment, a fourth seal 284 is also provided between the side of the guide portion 28b remote from the connection portion 202 and the first housing 1 for sealing the air duct 11. Illustratively, the fourth seal 284 may also be one or more of a backing adhesive, foam, or silicone.

In yet another alternative embodiment, a third sealing member may be disposed on the surface of the guiding portion 28b away from the heat dissipating fan 26, and a fourth sealing member may be disposed between the side of the guiding portion 28b away from the connecting portion 202 and the first housing 1 for sealing the air duct 11.

In summary, in either of the above-mentioned manners, the purpose is to seal the air duct 11, and to avoid the situation that the airflow in the air duct 11 is already dispersed to other positions and affects the heat dissipation effect when the airflow is not sucked into the heat dissipation fan 26.

The distribution of the channels and how the heat dissipation fan 26 guides the airflow of the air duct 11 to the air outlet 10 will be briefly described below with reference to the above components.

As can be seen from the foregoing, the air duct 11 includes the first air duct 11a and the second air duct 11b, the first air duct 11a is located between the main machine 2 and the first cover plate 141, and the second air duct 11b is located between the main machine 2 and the second cover plate 142, specifically, the first air duct 11a can pass through the main circuit board 22a and the side of the optical engine light source 20a facing the first frame portion 13, and the second air duct 11b can pass through the main circuit board 22a, the sub circuit board 22b and the side of the optical engine light source 20a facing the covering portion 14, so that during heat dissipation, air enters the first housing 1 via the first air inlet and the second air inlet, passes through the first air duct 11a and the second air duct 11b respectively, is transmitted to the fusion area 111 (or the circulation space 201a) by the first air duct 11a and the second air duct 11b, and then is blown to the air outlet 10 via the heat dissipation fan 26. Therefore, the independence (i.e., sealing) between the first air duct 11a and the second air duct 11b is critical to ensure the efficient operation of the two air ducts 11.

Therefore, in the present embodiment, the first sealing member is disposed between the first cover plate portion 141 and the host 2 and the first sealing member is disposed between the host 2 and the second cover plate portion 142, so that the first air duct 11a and the second air duct 11b can be kept independent from each other at the air inlet, thereby avoiding mutual interference of heat, and meanwhile, the sealing of the connection portion of the heat dissipation fan 26 and the channel (i.e. the circumference of the heat dissipation fan 26) is the last checkpoint of the sealing of the air duct 11, therefore, in the present embodiment, the second sealing member is disposed on the side of the heat dissipation fan 26 away from the air inlet side 26a and the side of the heat dissipation fan 26 away from the air outlet side 26b, then the third sealing member 283 is disposed on the surface of the guide portion 28b connected with the heat dissipation fan 26 away from the heat dissipation fan 26, and the fourth sealing member 284 is further disposed between the side of the guide portion 28b away from the connection portion, The third sealing member 283 and the fourth sealing member 284 are arranged to completely seal the first air duct and the second air duct, so as to ensure the air duct 11 of the suction type heat dissipation fan 26 to have good sealing performance and thus ensure heat dissipation efficiency.

In some embodiments, in order to limit the fixing of the heat dissipation bracket on the optical engine bracket 20c and prevent the heat dissipation bracket from being detached from the optical engine bracket 20c, the host 2 may further include a limiting member 29, at least one end of the limiting member 29 may be fixed on the auxiliary bracket 28, and the limiting member 29 is connected to an end of the heat dissipation bracket away from the protrusion 201c to limit the heat dissipation fan 26. Specifically, the position-limiting member 29 may be a concave-shaped position-limiting strip, and the position-limiting member 29 and the auxiliary bracket 28 may enclose a position-limiting space, so as to limit a position of an end of the heat dissipation fan 26 away from the protrusion 201c and prevent the heat dissipation fan from being separated from the protrusion 201c and the auxiliary bracket 28.

As shown in connection with fig. 15, in some embodiments, control assembly 22 may be at least partially disposed on connection portion 202. To facilitate the arrangement of the control assembly 22, a boss 202a having a hollow opening may be protruded from the connecting portion 202, and the control assembly 22 may be at least partially disposed in the hollow portion of the boss 202 a. Specifically, the control component 22 may include a main circuit board 22a, and the main circuit board 22a may be disposed on the boss 202a of the connection portion 202, that is, the main circuit board 22a is located on a side of the light engine 20a away from the light engine component 20, so that the main circuit board 22a and the light engine component 20 may be reasonably arranged on one hand, and distributed in several orientations of the whole machine, and at least a portion of the air duct 11 may pass through an area where the main circuit board 22a is located and may also pass through an area where the light engine component 20 is located, so that the air duct 11 may discharge heat generated by the main circuit board 22a and heat generated by the light engine component 20a to the air outlet 10. On the other hand, the main circuit board 22a is disposed on a side of the carriage light source 20a away from the carriage assembly 20, so that the main circuit board 22a can also prevent the carriage light source 20a from blocking light.

It is understood that the main circuit board 22a refers to a main board of the head-mounted device, which is mainly used for controlling the operation and processing of each functional device in the head-mounted device, and therefore, a plurality of main chips for controlling the operation and processing of each functional device in the head-mounted device may be disposed on the main circuit board 22 a.

In order to satisfy the wiring requirements of the devices of the main unit 2 in consideration of more functional devices in the main body device 100, the control assembly 22 further includes a sub circuit board 22b electrically connected to the main circuit board 22a, and the sub circuit board 22b may be located between the two opto-mechanical light sources 20 a. Specifically, the sub circuit board 22b and the main circuit board 22a may be connected by a flexible circuit board 22c, and when the sub circuit board 22b and the main circuit board 22a are connected by the flexible circuit board 22c, a bending structure may be formed substantially, that is, the whole area (e.g., length, width) of the main circuit board 22a may be larger than the whole area (e.g., length, width) of the sub circuit board 22b, and the sub circuit board 22b is connected to the middle position of the main circuit board 22a by the flexible circuit board 22c and forms a space with the main circuit board 22a, that is, the sub circuit board 22b is located below the main circuit board 22a, and a plurality of sub chips may also be disposed on the sub circuit board. During wiring, the sub circuit board 22b is disposed in the hollow portion of the boss 202a of the connecting portion 202, and is disposed close to the first camera module 241, so that the first camera module 241 can be electrically connected to the sub circuit board 22b, and the electrical connection can be achieved through wires, flexible circuit boards or connectors. Since the main circuit board 22a is longer than the sub circuit board 22b, two ends of the main circuit board 22a can extend to positions close to the two carriage light sources 20a, so that the two carriage light sources 20a can be electrically connected to the main circuit board 22a, and the two second camera modules 242 disposed at two ends of the supporting portion 201 can also be electrically connected to the main circuit board 22 a.

Considering that the main circuit board 22a, the sub circuit board 22b, the camera module 24 and the opto-mechanical light source 20a are all disposed on the opto-mechanical support 20c, in order to avoid heat accumulation between the above components, heat dissipation fins may be disposed on one or more of the sub circuit board 22b and the first camera module 241, the main circuit board 22a and the opto-mechanical light source 20a, and the opto-mechanical light source 20a and the second camera module 242, and heat dissipation fins may be utilized to conduct heat so as to avoid heat concentration.

In some embodiments, to support the fixed secondary circuit board 22b, the control assembly 22 may further include a secondary board support 22d, which may be located between the connection portion 202 and the secondary circuit board 22b and is used to support the secondary circuit board 22 b. Specifically, the sub-plate holder 22d may be provided in the hollow portion of the boss 202a on the connection portion 202. The sub-board holder 22d is disposed in the hollow portion of the boss 202a on the connection portion 202, and the space in the height direction of the opto-mechanical holder 20c can be utilized, so that the arrangement of the opto-mechanical holder 20c and the sub-board holder 22d in the first housing 1 is more compact, and the occupation of the space of the first housing 1 is reduced.

Referring to fig. 16 to 17, in some embodiments, the main device 100 further includes a heat sink module 4, and the heat sink module 4 may include a heat sink base plate 41, and the heat sink base plate 41 may be located between the main circuit board 22a and the sub circuit board 22b for dissipating heat of the main circuit board 22a and the sub circuit board 22 b. Specifically, the heat dissipation bottom plate 41 may be a strip-shaped plate, which may be disposed on the carriage support 20c, and the length direction of the heat dissipation bottom plate 41 may be along the length direction of the carriage support 20 c. The heat dissipation base plate 41 can extend to the positions of the two supporting portions 201 of the optical engine support 20c, and the heat dissipation base plate 41 can include an upper surface 410 and a lower surface 411 which are opposite to each other, so that the main circuit board 22a can be attached to the upper surface 410 of the heat dissipation base plate 41, and the sub circuit board 22b can be attached to the lower surface 411 of the heat dissipation base plate 41, and thus, the heat generated by the main chip and the negative chip on the main circuit board 22a and the sub circuit board 22b can be conducted by using the heat dissipation base plate 41, and effective heat dissipation of the main circuit board 22a and the sub circuit board 22b can be realized.

Further, the heat dissipation module 4 may further include two heat dissipation fin structures 42, the two heat dissipation fin structures 42 are respectively disposed on two ends of the heat dissipation base plate 41, the two heat dissipation fin structures 42 and the heat dissipation base plate 41 may enclose a receiving area 412, and the main circuit board 22a may be located in the receiving area 412. In this way, the heat generated by the main chip and the sub-chip on the main circuit board 22a and the sub-circuit board 22b is conducted to the heat dissipation fin structure 42 by the heat dissipation bottom plate 41, thereby further improving the heat dissipation effect.

Alternatively, the two fin structures 42 may be attached to the heat sink base plate 41 by an adhesive. It is understood that in other embodiments, the two heat sink fin structures 42 can be connected to the heat sink base plate 41 by screw fastening or other fastening means (e.g., snap fastening).

In addition, in order to improve the efficiency of the heat sink base plate 41 in transferring heat to the heat sink fin structures 42, a heat conductive sheet (e.g., a graphite sheet) may be disposed between the heat sink fin structures 42 and the heat sink base plate 41 to improve the heat transfer efficiency.

Alternatively, the two heat dissipation fin structures 42 may be respectively disposed corresponding to the two optical machine light sources 20a, so that the two heat dissipation fin structures 42 can dissipate the heat generated by the two optical machine light sources 20a in time. In actual implementation, since the heat dissipation base plate 41 is disposed on the optical engine bracket 20c, specifically, the connection portion 202 and the supporting portion 201, when the two heat dissipation fin structures 42 are disposed on two ends of the heat dissipation base plate 41, the two heat dissipation fins can be located above the two optical engine light sources 20a (i.e., the backlight end of the optical engine light sources 20 a).

Specifically, the heat dissipation fin structure 42 includes a plurality of fins 420 arranged at intervals, a heat dissipation channel 421 is formed between two adjacent fins 420, and the heat dissipation channel 421 may be communicated with the air duct 11, or may be formed as a part of the air duct 11, in other words, the heat dissipation channel 421 may be communicated with the air inlet 12, so that the heat of the main circuit board 22a and the sub circuit board 22b is transferred to the heat dissipation fin 420 structure 42 through the heat dissipation bottom plate 41, so as to be concentrated on the heat dissipation channel 421, and the heat generated by the optical engine light source 20a is directly transferred to the heat dissipation channel 421 through the heat dissipation fin 420 structure 42, and then enters the air duct 11 through the heat dissipation channel 421, and finally is sucked into the air outlet 10 by the heat dissipation fan 26 to be discharged.

Specifically, in the present embodiment, since the heat dissipation fin structures are disposed on the optical engine bracket 20c, that is, the heat dissipation fin structures are closer to the first cover plate portion 141 of the first casing 1, the heat dissipation channel 421 between two adjacent fins of each heat dissipation fin structure is actually formed as a part of the air duct 11, so that the external air enters the first casing 1 through the air inlet 12, and the heat generated by the optical engine light source 20a, the main circuit board 22a, and the auxiliary circuit board 22b is pushed along the heat dissipation channel 421 to move towards the heat dissipation fan 26, so that the heat can be absorbed by the heat dissipation fan 26 and exhausted from the air outlet.

It can be seen that, in this embodiment, in addition to the design of the air duct 11, corresponding designs are also made for the heat transmission paths of the optical engine light source 20a, the main circuit board 22a, and the sub circuit board 22b, which are mainly realized by the heat dissipation base plate 41 and the heat dissipation fin structure 42, and the channels pass through the heat dissipation base plate 41 and the heat dissipation fin structure 42, so as to be successfully merged with the heat dissipation channels 421 of the heat dissipation fin structure 42.

In addition, in the embodiment, the main circuit board 22a, the auxiliary circuit board 22b and the optical engine light source 20a are intensively arranged near the heat dissipation base plate 41 and the heat dissipation fin structure 42, so that heat can be conveniently and quickly led out, and the heat dissipation efficiency is effectively improved.

In some embodiments, the heat dissipation base plate 41 and the heat dissipation fin structure 42 may be made of aluminum alloy, magnesium-aluminum alloy, or magnesium-lithium alloy, so as to have good heat conduction and heat dissipation performance. In addition, the heat dissipation base plate 41 and the heat dissipation fin structure 42 made of aluminum alloy, magnesium-aluminum alloy, and magnesium-lithium alloy are light and thin as a whole, so that the overall weight of the main body device 100 can be reduced, and the main body device 100 is more light and convenient as a whole.

It is understood that, in other embodiments, in addition to the above combination of the heat dissipation base plate 41 and the two heat dissipation fin structures 42, the heat dissipation module 4 of the present application may further add a vc (vapor chamber) soaking plate or a water cooling system (for example, a water cooling system is disposed on the heat dissipation base plate 41) on the heat dissipation base plate 41, and the heat dissipation effect can also be effectively improved.

In some embodiments, as shown in fig. 18 to fig. 19, to facilitate the installation of the heat dissipation module 4, the heat dissipation base plate 41 may be fastened to the optical engine bracket 20c by a first fastening member 413, and the heat dissipation base plate 41 may be fastened to the main circuit board 22a by a second fastening member 414, so as to connect the heat dissipation module 4 to the optical engine bracket 20c and the main circuit board 22 a. Specifically, in order to improve the locking effect, the first fastening member 413 may be locked with the two supporting portions 201 of the carriage 20c through two ends of the heat dissipating bottom plate 41, respectively, while the second fastening member 414 may be locked with the heat dissipating bottom plate 41 through the main circuit board 22a, and in order not to affect the connection between the sub circuit board 22b and the heat dissipating bottom plate 41, the second fastening member 414 may also be locked with two ends of the heat dissipating bottom plate 41 through two ends of the main circuit board 22a, respectively. It is understood that in other embodiments, the heat dissipating base plate 41 can be connected to the opto-mechanical support 20c and the main circuit board 22a by means of bonding, or by means of snap-fitting, etc.

The first fastener 413 and the second fastener 414 may be screws or bolts.

In order to further lock the heat sink module 4 and the main circuit board 22a, the heat sink module 4 further includes a pressing plate bracket 43, the pressing plate bracket 43 includes a first pressing plate portion 430 and a second pressing plate portion 431, which are connected to each other, the first pressing plate portion 430 and the main circuit board 22a are locked to the heat sink base plate 41 by a third fastening member 430a, and the second pressing plate portion 431 and the main circuit board 22a are locked to the heat sink base plate 41 by a fourth fastening member 431 a. Specifically, the first pressure plate portion 430 and the second pressure plate portion 431 are substantially in the shape of a long plate, and are connected to form an approximately L-shaped structure, the first pressure plate portion 430 presses the main circuit board 22a against the heat dissipation base plate 41 through the third fastening member 430a, and the second pressure plate portion 431 presses the main circuit board 22a against the heat dissipation base plate 41 through the fourth fastening member 431a, so that the connection stability between the main circuit board 22a and the heat dissipation base plate 41 is effectively ensured.

More specifically, one end of the first pressing plate 430 is covered on one side of the main circuit board 22a away from the optical mechanical assembly and locked with the main circuit board 22a by a third fastener 430a, and the first pressing plate 430 is bent and pressed against one side of the main circuit board 22a, the optical mechanical assembly and the heat dissipation module 4. One end of the second pressing plate portion 431 is connected to the other end of the first pressing plate portion 430, and abuts against the surface of the main circuit board 22a away from the optical engine assembly, and the other end of the second pressing plate portion 431 is locked with the middle portion of the heat dissipation bottom plate 41 through a fourth fastening member 431 a.

Alternatively, the third and fourth fasteners 430a and 431a may be screws or bolts.

It is understood that one or more of the platen holders 43 may be provided, for example, two platen holders 43 may be provided, and two platen holders 43 may be respectively disposed at both ends of the heat-dissipating base plate 41. Of course, the platen bracket 43 may also be three, four or more.

Specifically, the main circuit board 22a, the heat dissipation base plate 41, and the carriage 20c are roughly installed as follows:

the heat dissipation base plate 41 is fixed to the optical engine support 20c by the first fastening member 413 and the second fastening member 414, then the main circuit board 22a is placed on the heat dissipation base plate 41, and then the first pressure plate portion 430 and the second pressure plate portion 431 press the main circuit board 22a against the heat dissipation base plate 41 by the third fastening member 430a and the fourth fastening member 431a, respectively, thereby completing the connection between the main circuit board 22a and the heat dissipation base plate 41, and between the heat dissipation base plate 41 and the optical engine support 20 c.

As shown in fig. 20, the main body device 100 further includes a nose pad assembly 5, the nose pad assembly 5 includes a pad 51, a nose pad bracket 52 connected to the pad 51, and an installation portion 53 connected to an end of the nose pad bracket 52 far from the pad 51, and the installation portion 53 is connected to the first housing 1 or the installation portion 53 can extend into the first housing 1 to be connected to the host 2. Specifically, the mounting portion 53 may include a clamping block, and the first housing 1 or the host 2 includes a clamping groove, and the clamping block is detachably clamped with the clamping groove.

In an alternative embodiment, the mounting portion 53 and the first housing 1 may be mounted and connected by forming a slot for the mounting portion 53 to extend into on the first housing 1, so that the mounting portion 53 and the first housing 1 are mounted and connected.

In an alternative embodiment, the mounting portion 53 may also be bonded to the first housing 1.

In yet another alternative embodiment, the mounting portion 53 may extend into the first casing 1 to be mounted and connected with the host 2. Specifically, a clamping groove for the installation portion 53 to extend into is formed in the first casing 1, and the clamping groove can be communicated to the optical machine support 20c of the host machine 2, so that the installation portion 53 can be fixed to the optical machine support 20c, installation stability of the installation portion 53 and the first casing 1 is improved, and the installation portion 53 is prevented from falling out of the first casing 1.

In this embodiment, considering that the optical engine bracket 20c is provided with the sub-board bracket 22d, in order to further improve the installation stability of the installation part 53, the slot on the first housing 1 may also extend to the sub-board bracket 22d, so that the installation part 53 extends from the first housing 1 to be connected with the optical engine bracket 20c and the sub-board bracket 22 d.

The following description is made of the channel and heat source conditions of the main body apparatus 100 of the first embodiment:

a first air outlet 10a and a second air outlet 10b are respectively disposed at two ends of the covering portion 14, a heat dissipation fan 26 is respectively disposed at the first air outlet 10a and the second air outlet 10b, a first air inlet 121 and a second air inlet 122 are respectively disposed on the first cover plate portion 141 and the second cover plate portion 142, the first air channel is located between the first cover plate portion 141 and the host 2 and sequentially passes through one side of the main circuit board 22a facing the first frame portion 13, the heat dissipation bottom plate 41, the heat dissipation fin structure 42, the optical engine light source 20a and the second camera module 242, and the second air channel is located between the second cover plate portion 142 and the host 2 and sequentially passes through one side of the main circuit board 22a facing the covering portion 14, the heat dissipation bottom plate 41, the first camera module 241, the heat dissipation fin structure 42, the optical engine light source 20a and the second camera module 242, so that the main circuit board 22a is utilized by the heat dissipation fan 26, The heat of the optical engine light source 20a and the second camera module 242 is absorbed to the fusion area 111 through the first air duct 11a, and simultaneously the heat of the main circuit board 22a, the optical engine light source 20a, the first camera module 241, the optical engine light source 20a and the second camera module 242 is absorbed to the fusion area 111 through the second air duct 11b, so that the heat of the first air duct 11a and the heat of the second air duct 11b are fused in the fusion area 111, and are further absorbed to the first air outlet 10a and the second air outlet 10b through the cooling fan 26 and are discharged.

With the main body device 100 of the first embodiment, the heat dissipation fan 26 is disposed at the position of the air outlet 10, and the air outlet 10 is disposed at the end of the first casing 1, so that the main circuit board 22a and the auxiliary circuit board 22b can be disposed at the middle position of the optical engine bracket 20c, that is, the middle position of the first casing 1, and thus, the main circuit board 22a and the optical engine light source 20a can be communicated into a whole by using one heat dissipation module 4, so that the maximum heat dissipation effect can be achieved by using the minimum number of air channels 11. Meanwhile, the length of the air duct 11 can be increased, and flowing air can contact with a heat source as much as possible, so that the heat dissipation efficiency is increased. In addition, by using the active air suction manner adopted by the heat dissipation fan 26, heated air of each heat source is not mixed together, so that the heat sources with different temperatures can be respectively cooled and processed without mutual interference.

Further, the heat dissipation fan 26 is disposed at two ends of the optical engine support 20c, and the middle space area of the optical engine support 20c can be reserved for the first camera module 241, so that the coordination of the appearance design of the main body device 100 is facilitated.

Further, heat sources (i.e., the main circuit board 22a, the auxiliary circuit board 22b, the first camera module 241, the optical engine light source 20a, and the second camera module 242) are reasonably distributed on the heat dissipation base plate 41 and the heat dissipation fin structures 42, specifically, the main circuit board 22a and the auxiliary circuit board 22b are respectively arranged on the upper surface and the lower surface of the heat dissipation base plate 41, so that heat can be directly conducted through the heat dissipation base plate 41, and then connected with the optical engine light source 20a through the heat dissipation base plate 41, and then conducted to the heat dissipation fin structures 42 above the optical engine light source 20a, thereby achieving the purpose of rapid heat dissipation and cooling in a small volume.

Further, since the first air duct 11a and the second air duct 11b are sealed independently before the fusion area 111, the air volume and the air pressure of each air duct 11 can be flexibly controlled by changing the shapes, the air resistances, the sizes of the air ducts 11, and the like of the first air duct 11a and the second air duct 11b, and the temperature of each area needing cooling, through which the air ducts 11 pass, can be accurately controlled.

Example two

Referring to fig. 21 to 22, a second embodiment of the invention discloses a head-mounted apparatus 1000, the head-mounted apparatus 1000 includes a wearing portion and the main device 100 as described in the first embodiment, and the wearing portion 1001 is used for connecting the first housing 1 to wear the main device 100 on the head of the user. Specifically, the wearing parts 1001 may be connected to both ends of the first housing 1 in the longitudinal direction, so that the main body device 100 may be worn on the head of the user.

In some embodiments, the wearing portion 1001 may be a temple or a headband. When the wearing part 1001 is a temple, the temple may be two, two temples are respectively connected to both ends of the first casing 1 in the length direction, and the two temples are respectively used for being erected on the ear of the human body, thereby enabling the main body device 100 to be worn on the head of the human body. Of course, when the wearing portion 1001 is a headband, the main body device 100 can be worn on the head of a human body by the headband.

In some embodiments, the air outlet 10 may be located at a connection position between the wearing portion 1001 and the first casing 1, so that the air outlet 10 may be hidden at the connection position between the wearing portion 1001 and the first casing 1, and thus the user may not easily see the air outlet 10, and the air outlet 10 is not easily touched, so that the air outlet 10 is hidden, and the integrity and the aesthetic property of the appearance shape of the whole head-mounted device 1000 are both very favorable. In addition, the user can not touch and perceive the high-temperature hot air of the air outlet 10, so that the use experience of the user on the head-mounted device 1000 is effectively improved.

Furthermore, the wearing portion 1001 may have an air inlet corresponding to the air outlet 10, a cavity communicating with the air inlet 12, and an air outlet 282, so that the air from the air outlet 10 can be sequentially discharged through the air inlet (not shown), the cavity (not shown), and the air outlet (not shown), and further the heat generated by the host 2 in the first housing 1 can be timely discharged to the outside of the wearing portion 1001, thereby preventing the heat from being accumulated on the head of the human body.

In some embodiments, the wearing portion 1001 may include a second housing 1001a and an interface assembly 1001b, the second housing 1001a may be used to connect with the first housing 1, the interface assembly 1001b may be disposed on the second housing 1001a, and the interface assembly 1001b is electrically connected to the host 2 in the first housing 1 through an electrical connector 1001c, and the interface assembly 1001b may be used to connect with an external device. Specifically, as can be seen from the foregoing, the wearing portion 1001 may include a temple, one end of which is rotatably connected to the first casing 1, and the interface component 1001b may be disposed at an end of the temple facing away from the first casing 1, for example, on an end of the temple facing away from the first casing 1, for facilitating connection with an external device, which may be directly connected to the interface component 1001 b.

It is understood that the interface component 1001b may be a serial interface, such as a USB interface meeting USB 2.0 specification, USB3.0 specification, and USB3.1 specification, including: micro USB interface or USB TYPE-C interface. Further, interface component 1001b may also be any other type of serial interface capable of being used for serial data transfer. The interface component 1001b may be a charging interface or a data interface, and when the interface component 1001b is the charging interface, the external device may be an external power source. When the interface component 1001b is a data interface, the external device may be a data processing apparatus (e.g., a mobile phone, a tablet computer, a notebook computer, etc.).

Further, the electrical connector 1001c may be a wire or a flexible circuit board, and the electrical connector 1001c may be disposed in the second housing 1001a and extend into the first housing 1 through the second housing 1001a to be electrically connected to the main circuit board 22a of the host 2 in the first housing 1, so that the overall appearance of the wearing portion 1001 is simple, and no routing position is seen, which is not only beneficial to improving the appearance decoration effect of the head-mounted device 1000, but also beneficial to improving the electrical connection reliability of the interface assembly 1001b and the host 2, and avoiding the situation of electrical connection interruption possibly caused by the exposure of the electrical connector 1001 c.

In some embodiments, the wearing portion 1001 may further include a functional device (not shown) provided in the second housing 1001a, and the functional device may be electrically connected to the host 2 through the above-described electrical connector 1001c or another electrical connector 1001 c. Specifically, the functional device can be electrically connected to the host 2 through the above-described electrical connector 1001c, so that the provision of the electrical connector 1001c can be omitted, the component cost can be reduced, and the wiring can be facilitated. It will be appreciated that in other embodiments, the functional device may also be electrically connected to the host 2 through another electrical connector 1001c, for example, a lead wire or a flexible circuit board may be additionally provided to electrically connect to the host 2.

Alternatively, the functional device may include a speaker, a microphone, or other functional devices, etc. Providing the functional components in the second housing 1001a can reduce the number of functional components arranged in the first housing 1, thereby reducing the occupation of the internal space in the first housing 1 and reducing the overall mass of the main body apparatus 100, and at the same time, since this portion of the functional components also generates heat when operating, providing this portion of the functional components in the second housing 1001a can reduce the concentration of heat in the first housing 1.

It should be noted that the head-mounted device 1000 of the present invention may implement different effects such as Virtual Reality (VR), Augmented Reality (AR), or Mixed Reality (MR) by transmitting optical signals to human glasses through various head display devices. Illustratively, the head-mounted device may be AR glasses, VR glasses, MR glasses, or the like.

Referring to fig. 23 and 24, the head-mounted device 1000 of the present invention may further include a data acquisition module 1002, a data output module 1003, and an integrated circuit module 1004. The data acquisition module 1002, the data output module 1003 and the integrated circuit module 1004 may be disposed in the first casing 1 or the wearing portion 1001. For example, the data acquisition module 1002, the data output module 1003 and the integrated circuit module 1004 may be disposed in the wearing portion 1001.

The integrated circuit module 1004 includes: the data conversion module 1004a and the interface module 1004b, the data conversion module 1004a is connected with the data acquisition module 1002 and the data output module 1003 respectively through the interface module 1004 b.

The data conversion module 1004a is configured to perform serialization conversion on the data acquired from the data acquisition module 1002 through the interface module 1004b, and output the converted serial data through the interface component 1001b, so as to process the converted serial data, for example, transmit the converted serial data to the host 2 or an electronic device (e.g., a mobile phone, a tablet computer, a smart watch, etc.) for processing, and the like.

The data conversion module 1004a is further configured to convert the serial data received through the interface component 1001b to convert the received serial data into interface data matching with an interface protocol of the interface module 1004b, and transmit the converted interface data to the data output module 1003 through the interface module 1004b, so as to output the converted interface data to a user through the data output module 1003.

The Integrated Circuit module 1004 may be implemented as an ASIC (Application Specific Integrated Circuit) data integration processing chip, for example, or may also be implemented as an FPGA (Field Programmable Gate Array).

In the head-mounted device provided in this embodiment, the data acquisition module 1002, the data output module 1003, the integrated circuit module 1004, and the like are disposed in the wearing portion 1001, that is, the head-mounted device 1000 of this embodiment uses an integrated circuit chip, performs data acquisition through an interface module in the integrated circuit chip, and performs centralized conversion on the acquired data and the data received from the host unit through the data conversion module, and the centralized conversion can reduce the overall data processing delay of the head-mounted device 1000.

Fig. 24 is a schematic diagram illustrating another configuration of a head-mounted device 1000 according to an example embodiment. The integrated circuit module 1004 in the head-mounted device 1000 as shown in fig. 24 includes a plurality of interface modules, for example, the plurality of interface modules may be an I2C interface module 10040, an SPI interface module 10041, an I2S interface module 10042, a SLIMBus interface module 10043, and an MIPI interface module 10044, respectively.

The I2C interface module 10040 communicates with connected modules using the I2C bus, which is a simple, bi-directional two-wire synchronous serial bus, I2C. It requires only two wires to transfer information between devices connected to the bus. The master device is used to initiate the bus to transfer data and generate a clock to open up the transferred devices when any addressed device is considered a slave device. The relationship of master and slave, send and receive on the bus is not constant, but depends on the direction of data transfer at the time. If the master device is to send data to the slave device, the master device addresses the slave device first, then actively sends the data to the slave device, and finally the master device terminates data transmission; if the master device is to receive the data of the slave device, the slave device is addressed by the master device first, then the master device receives the data sent by the slave device, and finally the master device terminates the receiving process. In this case, the master is responsible for generating the timing clock and terminating the data transfer. Generally, I2C is a control interface for transmitting control signaling.

The SPI interface module 10041 communicates with connected modules using an SPI bus. The SPI bus is a high-speed, full-duplex synchronous communication bus. The SPI communication principle is simple and it works in a master-slave mode, which usually has a master and one or more slaves, requiring 4 lines for master data input, master data output, clock signal transmission, and enable signal transmission for master output, respectively. Usually, the SPI interface is also a control interface for transmitting control signaling.

The I2S interface module 10042 communicates with connected modules using an I2S bus. The I2S bus is a bus standard established for audio data transmission between digital audio devices (e.g., CD players, digital sound processors, digital television sound systems). The design of independent wire transmission clock and data signal is adopted, and the data and clock signal are separated, so that the distortion caused by time difference is avoided, the cost for purchasing professional equipment for resisting audio jitter is saved for users, and the method is widely applied to various multimedia systems. A standard I2S bus cable is made up of 3 serial conductors: 1 is a Time Division Multiplexing (TDM) data line; 1 is a word selection line; the 1 root is the clock line.

The SLIMBus interface module 10043 communicates with connected modules using a SLIMBus bus. The SLIMBus bus is an audio interface specified by the MIPI alliance for connecting a baseband/application processor and an audio chip, typically for transmitting audio data. The two ends of the SLIMbus are composed of an interface device and one to a plurality of functional devices, the interface device and the functional devices are connected by one to a plurality of ports, and the ports can be only input, only output or bidirectional. The SLIMBus bus supports dynamic stop and restart and supports all sampling frequencies.

The MIPI interface module 10044 communicates with the connected modules using MIPI interface specifications. MIPI is an open standard and a specification established by the MIPI alliance for mobile application processors. The purpose is to standardize the interfaces in the mobile phone, such as a camera, a display screen interface, a radio frequency/baseband interface and the like, thereby reducing the complexity of the mobile phone design and increasing the design flexibility. The MIPI multimedia specification is largely divided into three layers, namely an application layer, a protocol layer and a physical layer. The interface mainly applies to the interfaces of the camera, the display and other devices, including the camera interface csi (camera Serial interface), the display interface dsi (display Serial interface) and so on.

As shown in fig. 24, the head-mounted device 1000 may further include a plurality of data acquisition modules 1002, for example, the plurality of data acquisition modules 1002 may be: an audio data acquisition module 1002a, a video data acquisition module 1002b, an eye tracking module 1002c, and a sensory data acquisition module 1002 d.

The audio data collection module 1002a may include a microphone and an audio Codec (Codec), for example. The audio codec audio-encodes the data collected by the microphone.

The video data acquisition module 1002b may include, for example, a camera, such as a lens of a general camera, an IR lens of an IR camera, and the like.

Eye tracking is a scientific application technology, when the eyes of a person look at different directions, the eyes can slightly change, the changes can generate extractable features, and a computer can extract the features through image capture or scanning, so that the changes of the eyes can be tracked in real time, the state and the demand of a user can be predicted, response is carried out, the purpose of controlling equipment by the eyes is achieved, and for example, the user can turn pages without touching a screen. In principle, eye movement tracking mainly studies the acquisition, modeling and simulation of eyeball movement information, and has wide application. Besides the eye tracker, the equipment for acquiring the eye movement information can also be image acquisition equipment, even a camera on a common computer or a mobile phone, and the eye movement information acquisition equipment can also realize eye tracking under the support of software.

Eye tracking module 1002c may include an eye tracker, an image capture device, or the like.

The sensing data acquisition module 1002d may include, for example: proximity sensors (Proximity sensors), IMDs (Inertial Measurement units), visible Light sensors (Ambient Light sensors), and the like.

Among them, the proximity sensor is a generic name of a sensor for detecting without touching a detection object, instead of a contact detection method such as a limit switch. The movement information and the presence information of the detection object can be converted into an electric signal. The detection principle of the induction type proximity sensor is to detect a magnetic loss caused by an eddy current generated on a surface of a conductor by the influence of an external magnetic field. An alternating magnetic field is generated in the detection coil, and a change in impedance due to an eddy current generated in the metal body of the detection body is detected. In addition, as another embodiment, an aluminum detection sensor that detects a frequency-phase component, an all-metal sensor that detects only an impedance change component by a working coil, and the like are included.

IMD is a device for measuring the three-axis attitude angle (or angular rate) and acceleration of an object. Generally, an IMU includes three single-axis accelerometers and three single-axis gyroscopes, the accelerometers detect acceleration signals of an object in three independent axes of a carrier coordinate system, and the gyroscopes detect angular velocity signals of the carrier relative to a navigation coordinate system, and measure angular velocity and acceleration of the object in three-dimensional space, and then solve the attitude of the object.

The visible light sensor is a device which takes visible light as a detection object and converts the visible light into an output signal. The visible light sensor can sense the regularly measured quantity and convert the regularly measured quantity into a device or a device of a usable output signal.

As shown in fig. 24, the audio data collection module 1002a may be connected to the data conversion module 1004a through the SLIMBus interface module 10043 and the SPI interface module 10041, for example. Wherein, a control signal can be transmitted between the audio data collection module 1002a and the SPI interface module 10041, and audio data can be transmitted between the audio data collection module 1002a and the SLIMBus interface module 10043.

The video data collection module 1002b may be connected to the data conversion module 1004a through the MIPI interface module 10044 and the I2C interface module 10040, for example. Video data can be transmitted between the video data collection module 1002b and the MIPI interface module 10044, and a control signal can be transmitted between the video data collection module 1002b and the I2C interface module 10040.

Eye tracking module 1002c may be coupled to data conversion module 1004a, for example, via MIPI interface module 10044 and I2C interface module 10040. Eye tracking data can be transmitted between the eye tracking module 1002c and the MIPI interface module 10044, and control signals can be transmitted between the eye tracking module 1002c and the I2C interface module 10040.

The sensing data collection module 1002d may be connected to the data conversion module 1004a via the I2C interface module 10040, for example. The sensing data acquisition module 1002d may transmit sensing data and control signals to the I2C interface module 10040.

With continued reference to fig. 24, the head-mounted device 1000 may also include a plurality of data output modules 1003, for example. The plurality of data output modules 1003 may include, for example, a display module 1003a and an audio data output module 1003 b.

The display module 1003a may be, for example, a light source of the host 2 as mentioned in the above embodiment.

The audio data output module 1003b may include, for example, a speaker and/or a headphone interface, and outputs audio data through an external headphone.

The display module 1003a may be connected to the data conversion module 1004a through the MIPO interface module 1004b and the I2C interface module 10040, for example. The display module 1003a and the MIPO interface module 1004b may transmit video data to be displayed, and the display module 1003a and the I2C interface module 10040 may transmit a control signal.

The audio data output module 1003b may be connected with the data conversion module 1004a through the I2S interface module 10042 and the I2C interface module 10040, for example. The audio data output module 1003b and the I2S interface module 10042 can transmit audio data to be output, and the audio data output module 1003b and the I2C interface module 10040 can transmit control signals.

The integrated circuit module 1004 may further include a clock module 1004c, which is respectively connected to the data conversion module 1004a and the interface modules 1004b, and is configured to output a clock signal to each module.

In some embodiments, the integrated circuit module 1004 may further include: a data compression module 1004d and a data decompression module 1004 e.

The data compression module 1004d and the data decompression module 1004e are respectively connected between the data conversion module 1004a and the interface component 1001 b.

The data compression module 1004d is configured to compress serial data to be output before the data conversion module 1004a outputs the converted serial data through the interface component 1001b, and output the compressed serial data through the interface component 1001 b.

The data decompression module 1004e is configured to decompress serial data received through the interface component 1001b before the data conversion module 1004a receives the serial data through the interface component 1001b, and transmit the decompressed serial data to the data conversion module 1004a for conversion.

By compressing the data to be transmitted, the transmission bandwidth can be saved, and the transmission rate is improved, so that the real-time performance of the data is further ensured, and the user experience is improved. It should be noted that the present disclosure does not limit the data compression/decompression algorithm used, and the specific algorithm can be selected according to the requirement in practical application.

In some embodiments, the head mounted device 1000 may further include: the power management module 1006 is connected to the interface component 1001b, and is configured to receive, through the interface component 1001b, power provided by a power supply device connected to the interface component 1001b, so as to supply power to the host 2 and the modules.

According to the head-mounted device disclosed by the second embodiment of the invention, the wearing part is connected to the air outlet position of the first shell of the main body device, so that the wearing part can be used for hiding the position of the air outlet, the hiding of the air outlet is realized, and the appearance tidiness of the head-mounted device is effectively improved.

The main body device and the head-mounted device of the head-mounted device disclosed in the embodiments of the present invention are described in detail above, and specific examples are applied herein to explain the principles and embodiments of the present invention, and the description of the above embodiments is only used to help understand the main body device and the head-mounted device of the present invention and the core ideas thereof; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.

Claims (44)

1. A body apparatus of a head-mounted device, the body apparatus comprising:

the air conditioner comprises a first shell, a second shell and a control device, wherein an air outlet is formed in at least one of two ends of the first shell in the length extension direction; and

the host is accommodated in the first shell, at least one air duct is arranged between the host and the first shell, the air duct is communicated with the air outlet, and heat generated by the host is transmitted to the air outlet through the air duct and is discharged.

2. The main body device according to claim 1, wherein the first casing is provided with air outlets at both ends in the length extending direction, and the air outlets include a first air outlet at one end of the first casing and a second air outlet at the other end of the first casing.

3. Main body device according to claim 1, wherein the first housing is further provided with an air inlet located between two ends of the first housing, and the air duct is communicated with the air inlet and located between the air inlet and the air outlet.

4. The body device of claim 3, wherein the body device further comprises a lens, the first housing comprises a first frame portion and a covering portion, the first frame portion is used for mounting the lens, one end of the covering portion is connected to the first frame portion, the covering portion and the first frame portion form a receiving space for receiving the host, and the air inlet and the air outlet are disposed on the covering portion.

5. Main body arrangement according to claim 4, wherein the first housing further comprises an adapter part, one end of which is connected to the first frame part and the other end of which is connected to a wearing part for wearing the main body arrangement on the head of a user.

6. The body device of claim 5, wherein the junction between the adaptor portion and the first frame portion defines a vent, and outlet air from the outlet vents is exhausted through the vent.

7. The body device of claim 6, wherein at least a portion of a surface of the adapter portion is opposite to the air outlet, and the at least a portion of the surface is used for guiding air out of the air outlet.

8. Main body arrangement according to claim 7, wherein said at least partial surface encloses a recess recessed towards a side remote from said outlet opening, said recess being adapted to guide the outlet air of said outlet opening.

9. The body device according to claim 4, wherein the housing portion includes a cover plate portion connecting the first frame portion and side plate portions connected to both ends of the cover plate portion, the air outlet is provided in the side plate portions, and the air inlet is provided in the cover plate portion.

10. The body device of claim 9, wherein the cover portion comprises a first cover portion connected to the first frame portion and a second cover portion connected to the first cover portion, and the air channel comprises a first air channel between the host computer and the first cover portion and a second air channel between the host computer and the second cover portion.

11. The body arrangement of claim 10, wherein the first and second air paths are sealed such that the first and second air paths are at least partially not in communication.

12. The body device of claim 11, wherein the host computer abuts against an end of the second cover plate portion away from the first cover plate portion to seal the second air duct;

the main machine and the first cover plate part are tightly abutted to seal the first air duct, and/or a first sealing part is arranged between the main machine and the first cover plate part to seal the first air duct.

13. The body device of claim 10, wherein the first wind tunnel and the second wind tunnel have a fused region where wind from the first wind tunnel and the second wind tunnel merges.

14. The body apparatus of claim 13, wherein the merging area is adjacent to the air inlet, the first air duct and the second air duct share the air inlet, and the inlet air of the air inlet flows to the first air duct and the second air duct through the merging area respectively; alternatively, the first and second electrodes may be,

the fusion area is adjacent to the air outlet, the first air duct and the second air duct share the air outlet, and the air outlet of the first air duct and the air outlet of the second air duct flow to the air outlet through the fusion area.

15. The body device of claim 13, wherein at least one of the first air channel and the second air channel comprises a first sub-channel corresponding to the air inlet and a second sub-channel corresponding to the air outlet, and the fusion area is located between the first sub-channel and the second sub-channel.

16. The body device of claim 1, wherein the host comprises an optical-mechanical element and a control element, and heat generated by at least one of the optical-mechanical element and the control element is transmitted to the air outlet through the air channel and exhausted therefrom.

17. The body device of claim 16, wherein the opto-mechanical assembly comprises an opto-mechanical light source, an optical assembly, and an opto-mechanical mount, the opto-mechanical light source and the optical assembly being mounted on the opto-mechanical mount, the opto-mechanical light source being configured to emit light for transmission to a user via the optical assembly.

18. The main body device of claim 17, wherein the number of the optical-mechanical light sources includes two, the optical-mechanical support includes two support portions and a connecting portion connected between the two support portions, the two support portions are respectively used for supporting the two optical-mechanical light sources; the number of the optical assemblies corresponds to the number of the light sources of the light machine and is also two, and the control assemblies are at least partially arranged on the connecting parts.

19. The body device of claim 18, wherein the support portion comprises a sidewall structure having a hollow opening, the opto-mechanical light source is disposed on a side of the opening, and at least a portion of the optical assembly is disposed in the opening of the sidewall structure.

20. The device as claimed in claim 19, wherein the optical assembly includes a lens set, a first optical unit and a second optical unit, the lens set is mounted on an inner surface of the sidewall structure, the first optical unit is located on a side of the sidewall structure away from the optical engine light source, the second optical unit is disposed corresponding to the first optical unit, and the first optical unit is configured to guide the light received from the optical engine light source through the lens set to the second optical unit.

21. The body apparatus of claim 18, wherein the host further comprises a heat sink fan, the heat sink fan being located in the air channel.

22. The main body device of claim 21, wherein the heat dissipation fan is disposed adjacent to the air outlet and configured to guide the air from the air duct to the air outlet for being exhausted.

23. The main body device according to claim 21, wherein the number of the heat dissipation fans is two, and the two heat dissipation fans are respectively installed at two ends of the optical engine bracket.

24. The main body device of claim 21, wherein a side of the support portion facing away from the connecting portion and the first housing define a circulation space, the air duct includes the circulation space, and the heat dissipation fan is located in or adjacent to the circulation space and is configured to guide air in the circulation space to the air outlet for being discharged.

25. The main device of claim 24, wherein the heat dissipation fan is located on a side of the support portion away from the connecting portion, an air outlet side of the heat dissipation fan is opposite to the air outlet, and an air inlet side of the heat dissipation fan faces the support portion.

26. Main body arrangement according to claim 25, characterized in that at least one of the sides of the cooling fan facing away from the air inlet side and/or the side of the cooling fan facing away from the air outlet side is provided with a second sealing for sealing the air duct.

27. The main body device of claim 24, wherein a side of the support portion facing away from the connecting portion is provided with a protruding portion, a step structure is formed between the protruding portion and the support portion, at least a portion of the heat dissipation fan is disposed on and supported by the step structure, and the air outlet is located on a side of the heat dissipation fan away from the protruding portion.

28. The body apparatus of claim 27, wherein the main body further comprises an auxiliary bracket disposed on the support portion and located in the circulation space, and the heat dissipation fan is located on a side of the auxiliary bracket and the support portion away from the connection portion.

29. The body apparatus of claim 28, wherein the auxiliary holder includes a circulation portion and a guide portion connected to the circulation portion, the circulation portion is located between the guide portion and the support portion, the circulation portion has an air inlet hole, the guide portion has an air outlet hole, and air introduced into the circulation space can be introduced into the heat dissipation fan through the air inlet hole, a space between the guide portion and the support portion, and the air outlet hole in this order, and then guided to the air outlet by the heat dissipation fan.

30. Main body arrangement according to claim 29, wherein the surface of the guide remote from the radiator fan is further provided with a third seal for sealing the air duct; and/or a fourth sealing element is arranged between one side of the guide part, which is far away from the connecting part, and the first shell and is used for sealing the air duct.

31. The body device of claim 18, wherein the opto-mechanical support further comprises a fixed support, the fixed support is connected to at least one of the support portion or the connecting portion, and the main frame further comprises a camera assembly, and the camera assembly is fixed to the fixed support.

32. The body apparatus of claim 31, wherein the camera assembly includes a first camera assembly, the fixed bracket includes a first fixed bracket connected to the connecting portion and located between the two support portions, the first camera assembly is mounted on the first fixed bracket, and/or the camera assembly includes a second camera assembly, the fixed bracket includes a second fixed bracket disposed on a side of the support portions away from the connecting portion, the second camera assembly is mounted on the second fixed bracket.

33. The body apparatus of claim 18, wherein the control assembly includes a main circuit board disposed on a side of the opto-mechanical light source remote from the opto-mechanical assembly, at least a portion of the air channel passing through an area where the main circuit board is located.

34. The body apparatus of claim 33, wherein the control assembly further comprises a secondary circuit board electrically connected to the primary circuit board, the secondary circuit board being positioned between the two opto-mechanical light sources.

35. The body apparatus of claim 34, wherein the control assembly further comprises a secondary board support disposed between the connection portion and the secondary circuit board and configured to support the secondary circuit board.

36. The body device of claim 34, further comprising a heat sink module comprising a heat sink base plate positioned between the main circuit board and the secondary circuit board for dissipating heat from the main circuit board and the secondary circuit board.

37. The body device of claim 36, wherein the heat sink module further comprises two heat sink fin structures, the two heat sink fin structures are respectively disposed at two ends of the heat sink base plate, the two heat sink fin structures and the heat sink base plate define a receiving area, and the main circuit board is located in the receiving area.

38. The body apparatus of claim 37, wherein each of said heat sink fin structures includes a plurality of spaced apart fins, adjacent ones of said fins defining a heat sink channel therebetween, said heat sink channel forming a portion of said air channel.

39. The body device of any one of claims 1-38, further comprising a nose pad assembly, wherein the nose pad assembly comprises a pad, a nose pad bracket connected to the pad, and a mounting portion connected to an end of the nose pad bracket away from the pad, and the mounting portion is connected to the first housing or the mounting portion extends into the first housing and is connected to the host.

40. A head-mounted apparatus, characterized in that the head-mounted apparatus comprises a wearing part and the main body device as claimed in any one of claims 1 to 39, the wearing part is used for connecting the first shell to wear the main body device on the head of a user.

41. The headset of claim 40, wherein the air outlet is located at a connection between the wearable portion and the first housing.

42. The head-mounted apparatus of claim 41, wherein the wearing portion has an air inlet corresponding to the air outlet, a cavity communicating with the air inlet, and an air outlet, and the outlet air of the air outlet is discharged from the air outlet through the air inlet and the cavity.

43. The head-mounted apparatus of claim 40, wherein the wearing portion comprises a second housing and an interface assembly, the second housing is used for connecting with the first housing, the interface assembly is disposed on the second housing, the interface assembly is electrically connected with the host through an electrical connector, and the interface assembly is used for connecting with an external device.

44. The headset of claim 43, wherein the wearing portion further comprises a functional device disposed within the second housing, the functional device also being electrically connected to the host through the electrical connection or another electrical connection.

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