CN115220232A - Protective shell and head-mounted equipment - Google Patents

Abstract

The application provides a protective housing and a head-mounted device. The protective housing is used for accommodating a host of a head-mounted device, and includes a first housing including: a top plate; the first side plate is arranged on one side of the top plate; the second casing, with first casing lock to form and be used for holding the accommodation chamber of host computer, include: a bottom plate disposed opposite to the top plate; the second side plate is arranged on one side of the bottom plate and is opposite to the first side plate; the top plate and the bottom plate are used for being matched with the inner side face of the second side plate to form a first arc shape, the top plate and the outer side face of the bottom plate matched with the first side plate to form a second arc shape, and the bending degree of the second arc shape is larger than that of the first arc shape. This application is through with second casing and first casing lock are connected and are formed and hold the cavity to can hold the host computer, and play the guard action to the host computer.

Description

Protective shell and head-mounted device

The application is a divisional application of a Chinese invention patent application with the application number of 201911245209.3 and the name of 'protective shell and head-mounted equipment' applied in 2019, 12 months and 06 days.

Technical Field

The application relates to the technical field of intelligent equipment, in particular to a protective shell and a head-mounted device.

Background

Virtual Reality (VR) and Augmented Reality (AR) technologies can bring users with visual perception comparable to real scenes, and are currently popular research fields. To enable users to better experience VR and AR technology, VR and AR are typically displayed using a head-mounted device.

A head-mounted device is a wearable device worn on the head of a user, and a display screen for VR or AR display is positioned in front of the eyes of the user after wearing. Through in the display screen in the head-mounted device, the corresponding content is displayed in the area corresponding to wearing the left eye and the right eye of the user, so that the user can experience the display effect of VR or AR.

The head-mounted device can comprise a host which mainly comprises an optical machine component, a camera component, a mainboard and the like. These components of the host may be susceptible to damage caused by dropping or other factors. Therefore, the host needs to be effectively protected within the device.

Disclosure of Invention

One aspect of the present application provides a protective case for accommodating a host of a head-mounted device, the protective case comprising: a first housing comprising: a top plate; the first side plate is arranged on one side of the top plate; the second casing, with first casing lock to form and be used for holding the accommodation chamber of host computer, include: a bottom plate disposed opposite to the top plate; the second side plate is arranged on one side of the bottom plate and is opposite to the first side plate; the top plate and the bottom plate are used for being matched with the inner side face of the second side plate to form a first arc shape, the top plate and the outer side face of the bottom plate matched with the first side plate to form a second arc shape, and the bending degree of the second arc shape is larger than that of the first arc shape.

In another aspect, the present application also provides a protective case for accommodating a host of a head mounted device, the protective case comprising: a first housing comprising: a top plate; the first side plate is arranged on one side of the top plate; the second casing, with first casing lock includes: a bottom plate disposed opposite to the top plate; the second side plate is arranged on one side of the bottom plate and is opposite to the first side plate; a first connecting mechanism disposed between the top plate and the second side plate; the second connecting mechanism is arranged between the bottom plate and the first side plate; the first connecting mechanism and the second connecting mechanism enable the first shell and the second shell to be matched to form a containing chamber for containing the host.

In another aspect, the present application also provides a head mounted device comprising a first housing comprising: a top plate; the first side plate is arranged on one side of the top plate; the second casing, with first casing lock in order to form the accommodation chamber that is used for holding the host computer, include: a bottom plate disposed opposite to the top plate; the second side plate is arranged on one side of the bottom plate and is opposite to the first side plate; the tightness adjusting mechanism is arranged opposite to the protective shell; a strap assembly connecting two ends of the protective housing and opposite ends of the slack adjustment mechanism to form an endless frame, the strap assembly configured to extend into the slack adjustment mechanism such that the slack adjustment mechanism adjusts the length of the strap assembly; and the stress assembly is arranged on the annular frame.

This application through with the second casing with first casing lock is connected and is formed and hold the cavity to can be used for holding the host computer of head mounted device, and play the guard action to the host computer.

Drawings

In order to more clearly describe the technical solutions in the embodiments of the present application, the drawings required to be used in the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the application, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

Fig. 1 is a perspective assembly view of a head-mounted device in an embodiment of the present application;

FIG. 2 is an exploded perspective view of the head-mounted device of FIG. 1;

FIG. 3 is an exploded perspective view of the head-mounted device of FIG. 1 from another perspective;

FIG. 4 is a perspective assembly view of a first housing assembly of the head mounted device of an embodiment of the present application;

FIG. 5 is an exploded perspective view of the first housing assembly of FIG. 4;

FIG. 6 is an enlarged perspective view of the main front shell of the first housing assembly of FIG. 5;

FIG. 7 is a perspective view of the main front shell of FIG. 6 from another perspective;

FIG. 8 is an enlarged perspective view of the main rear housing of the first housing assembly of FIG. 5;

FIG. 9 is a perspective view of the main rear housing of FIG. 8 from another perspective;

FIG. 10 is an enlarged perspective view of the face shield of the first housing assembly of FIG. 5;

FIG. 11 is a schematic view of the mask of FIG. 10 from another perspective;

FIG. 12 is an enlarged schematic view of the rear cover of the first housing assembly of FIG. 5;

FIG. 13 is a schematic view of the main housing trim piece of FIG. 5 from another perspective;

FIG. 14 is an exploded view of the opto-mechanical assembly of FIG. 2;

FIG. 15 is a perspective view of the opto-mechanical mount of the opto-mechanical assembly of FIG. 14;

fig. 16 is a schematic perspective exploded view of a camera module of a head-mounted device according to an embodiment of the present disclosure;

fig. 17 is a perspective assembly view of the camera module and the optical mount of the head mounted device in the embodiment of the present application;

FIG. 18 is an exploded isometric view of the main board, speaker assembly and microphone assembly of the head mounted device in an embodiment of the subject application;

FIG. 19 is an exploded isometric view of the main panel, speaker assembly and microphone assembly of FIG. 18 from another perspective;

fig. 20 is an exploded perspective view of a first housing assembly of the head-mounted device and vision adjustment eyeglasses in an embodiment of the present application;

FIG. 21 is a cross-sectional view of the first housing assembly, the optics assembly, the camera assembly, the speaker and the main board of the head-mounted device of FIG. 1;

FIG. 22 is another cross-sectional view of the first housing assembly, the optical engine assembly, the camera assembly, the speaker and the main board of the head-mounted device of FIG. 1;

FIG. 23 is an exploded perspective view of the first housing assembly, the optics assembly, the camera assembly, the speaker and the main board of the head mounted device of FIG. 1;

FIG. 24 is a perspective assembled view of the strap assembly and the second housing assembly of FIG. 1;

FIG. 25 is a perspective assembled view of the first headband of the strap assembly of FIG. 24;

FIG. 26 is an exploded perspective view of the first headband of FIG. 25;

FIG. 27 is an exploded, perspective view, similar to FIG. 26, of the first head at another angle;

FIG. 28 is an enlarged perspective view of the portion circled A in FIG. 2;

FIG. 29 is a view similar to FIG. 24 showing the mating relationship of the power FPC to the associated components of the second housing assembly in the tie assembly;

FIG. 30 is a perspective assembled view of the second headband of the strap assembly of FIG. 24;

FIG. 31 is an exploded perspective view of the second headband of FIG. 30;

FIG. 32 is an exploded perspective view, similar to FIG. 31, of the second headband at another angle;

FIG. 33 is an enlarged perspective view of the portion circled B in FIG. 3;

FIG. 34 is an exploded perspective view of the second housing assembly;

FIG. 35 is a perspective assembled view of the second housing assembly;

FIG. 36 is a perspective assembled view of the rear bottom housing of the second housing assembly of FIG. 34, shown in assembled relationship with a battery;

FIG. 37 is a view of the assembled relationship of the rear housing and the power bracket of FIG. 36;

FIG. 38 is a perspective view similar to FIG. 34 of the rear sole shell of FIG. 34 at yet another angle;

FIG. 39 is an enlarged perspective view of the power bracket of FIG. 37;

fig. 40 is a perspective view of the connector of fig. 34.

FIG. 41 is an exploded perspective view of the slack adjustment mechanism;

FIG. 42 is a perspective view of the first housing of FIG. 41;

FIG. 43 is an exploded perspective view of the pawl assembly of FIG. 41;

FIG. 44 is an exploded isometric view similar to FIG. 43, of the pawl assembly of FIG. 41 from a further angle;

FIG. 45 is a partially assembled view of FIG. 44;

FIG. 46 is a perspective view of two of the pawls of FIG. 45;

FIG. 47 is a perspective view of a portion of the components of the pawl assembly of FIG. 41 assembled with the first housing;

FIG. 48 is a partial structural assembly view of the strap assembly and the tension adjustment mechanism;

FIG. 49 is an exploded perspective view of the knob assembly of FIG. 41;

FIG. 50 is a perspective exploded view, similar to FIG. 49, of the knob assembly of FIG. 41 from a further angle;

FIG. 51 is a partial assembled view of the strap assembly and the slack adjustment mechanism, similar to FIG. 48;

FIG. 52 is a perspective view of the first force receiving member of the force receiving assembly of FIG. 1 at another angle;

FIG. 53 is an exploded view of a second force-bearing member of the force-bearing assembly of FIG. 1 and a front chassis of the second housing assembly;

fig. 54 is an exploded perspective view of the second force-receiving member of fig. 53.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It should be apparent that the described embodiments are only a few embodiments of the present application, and not all 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 application.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

It is noted that the terms "first", "second", etc. are used herein for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, features defined as "first" and "second" may explicitly or implicitly include one or more of the described features.

Referring to fig. 1, a head-mounted device 100 according to an embodiment of the present disclosure may include a first housing assembly 10, a strap assembly 20 connected to two ends of the first housing assembly 10, a slack adjuster mechanism 40 connected to the strap assembly 20, a second housing assembly 30 disposed on the strap assembly 20 and opposite to the first housing assembly 10, and a force receiving assembly 50 disposed on the first housing assembly 10 and the second housing assembly 30. Wherein the first housing assembly 10, the strap assembly 20, and the second housing assembly 30 can form a frame with adjustable tightness to facilitate the wearing of the head-mounted device 100 on the head of the user. The force-bearing components 50 are disposed on the upper and lower sides of the frame for sharing the weight of the head-mounted device 100 borne by the head of the user.

With reference to fig. 2 and fig. 3, the head-mounted device 100 according to the embodiment of the present disclosure may further include a main unit housed in the first housing assembly 10, where the main unit may include an optical engine assembly 60, a camera assembly 70, a main board 80, a speaker assembly 91, a microphone assembly 92, and the like. Since the first housing assembly 10 is used for accommodating and protecting a host, the first housing assembly 10 can be also referred to as a host housing or a protection housing. The first housing assembly 10 and the host computer received therein may form a host computer assembly. The head mounted device 100 may be VR glasses, AR glasses, or the like. In the embodiments of the present application, AR glasses are described as an example.

In the example of AR glasses, the head mounted device 100 may be configured to communicate data to and receive data from an external processing device through a signal connection, which may be a wired connection, a wireless connection, or a combination thereof. However, in other cases, the head mounted device 100 may be used as a stand-alone device, i.e., data processing is performed on the head mounted device 100 itself. The signal connection may be configured to carry any kind of data, such as image data (e.g., still images and/or full motion video, including 2D and 3D images), audio, multimedia, voice, and/or any other type of data. The external processing device may be, for example, a gaming console, personal computer, tablet computer, smart phone, or other type of processing device. The signal connection may be, for example, a Universal Serial Bus (USB) connection, a Wi-Fi connection, a bluetooth or Bluetooth Low Energy (BLE) connection, an ethernet connection, a cable connection, a DSL connection, a cellular connection (e.g., 3G, LTE/4G, or 5G), or the like, or combinations thereof. Additionally, the external processing device may communicate with one or more other external processing devices via a network, which may be or include, for example, a Local Area Network (LAN), a Wide Area Network (WAN), an intranet, a Metropolitan Area Network (MAN), the global internet, or a combination thereof.

The first housing assembly 10 of the head mounted device 100 may mount display assemblies, optics, sensors, processors, and the like. In the example of AR glasses, the display component is designed to overlay an image on the user's view of their real-world environment, for example, by projecting light into the user's eyes. The head-mounted device 100 may also include an ambient light sensor, and may also include electronic circuitry to control at least some of the above-described components and perform associated data processing functions. The electronic circuitry may include, for example, one or more processors and one or more memories.

First housing assembly 10

Referring to fig. 4 and 5, a perspective assembly view and an exploded view of the first housing assembly 10 of the head-mounted device 100 according to the embodiment of the present disclosure are shown. The first housing assembly 10 may include a main front housing 11, a main rear housing 12 coupled to the main front housing 11 by a snap-fit connection, a mask 13 covering the front of the main front housing 11, a rear cover 14 located below the main rear housing 12 and coupled to a lower portion of the mask 13, and a main housing decoration 15 covering the top of the main front housing 11.

In this context, reference will be made to the orientations of "up", "down", "front", "back", "left" and "right" indicated in fig. 1 and 4. It will be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like herein, when used in the context of the present application, are intended to refer to the orientation or positional relationship illustrated in the drawings, and are used merely for convenience and to simplify the description and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be considered as limiting the present application.

Main front shell 11 of first housing assembly 10

Referring to fig. 6, the main front case 11 may include a top plate 111 and a first side plate disposed at one side of the top plate 111. The first side plate may include a first portion 112 disposed outside the top plate 111 and extending downward from both sides of the top plate 111, a second portion 113, and a connection portion 114 extending from the first portion 112 away from a mounting plate 122 (see fig. 8) of the main rear case 12, and the second portion 113 extends downward from the connection portion 114. The main front case 11 may have a substantially inverted L-shaped cross section. The main front case 11 may be an integrally injection molded part to increase the structural strength of the main front case 11.

The top plate 111 may be crescent-shaped, that is, the inner side 1111 of the top plate 111 is arc-shaped to approximately match with the forehead of the user, the outer side 1112 of the top plate 111 is also arc-shaped with a greater curvature than the inner side 111, and two ends of the inner side 1111 and two ends of the outer side 1112 are respectively close to each other, that is, the distance between the inner side 1111 and the outer side 1112 gradually decreases from the middle of the top plate 111 to the left and right sides. The top plate 111 may be disposed horizontally, and one or more receiving portions 1113 may be formed on both sides thereof. For example, one housing part 1113 is provided at a position on the top plate 111 at the front left, and one housing part 1113 is provided at a position on the top plate 111 at the front right. The receiving portion 1113 may be a groove for receiving a key segment 1622 of a key FPC (Flexible Printed Circuit, herein collectively referred to as FPC) 162 (see fig. 18). The receptacle 1113 may also partially receive the bottom portion of the side key 16. When the side key 16 is pressed, the boss 161 (see fig. 7) below the side key 16 is used to press the key segment 1622. In one embodiment, four side buttons 16 may be symmetrically installed on the top plate 111 away from the middle position thereof near the left and right sides, i.e., two side buttons 16 are provided on one side. The top plate 111 may also have one or more through holes 1114 for mounting to other components. Wherein some of the through holes 1114 may have threads therein to mate with screws; other through holes 1114 may not have threads therein for screws to pass through. Referring to fig. 7, the lower surface 1115 of the top plate 111 may also be provided with one or more snap features 1116 near the inner side 1111. In one embodiment, each of the snap structures 1116 is a hook. It can be understood that the buckle structure in the application is not limited to the hook, the bump, the slot, the groove, the through hole, etc., as long as the two structures can be mutually buckled together.

Throughout the description of the present application, it is to be noted that, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms herein can be understood in a specific context to one of ordinary skill in the art.

The first portion 112 extends downward from two sides of the outer side surface 1112 of the top plate 111, i.e. positions corresponding to the left and right sides of the eyes of the user, so that the top view profile of the first portion 112 is the same arc shape as the outer side surface 1112. The first portion 112 is symmetrically disposed on both sides of the top plate 111 with respect to the second portion 113. One or more channels 1160 for inputting sound can be formed on both sides of the first portion 112; for example, a channel 1160 is provided at the front left of the first portion 112 and a channel 1160 is provided at the front right of the first portion 112. Each channel 1160 may be defined within a bump 116. The entrance 1161 of the channel 1160 is located on the outer surface of the first portion 112 of the first side plate; for example, the inlets 1161 of the two channels 1160 may be located in the upper half of the first portion 112 of the first side plate. The outlet 1162 of the channel 1160 is located on the lower surface 1115 of the top plate 111. Each channel 1160 may be located at a rear position of receptacle 1113. The inlets 1161 of the two channels 1160 are located on the sides of the housing 10 and have opposite orientations. These channels 1160, which may also be referred to as microphone apertures, are used to transmit sound into a microphone component 92 (see fig. 18) disposed within the head-mounted device 100, thereby gathering sound data of the user and/or the external environment by the microphone component 92. The left and right ends of the inner surface 1122 of the first portion 112 of the first side panel may also be provided with one or more posts 1123 for connection with the strap assembly 20. In the assembled configuration of the main front housing 11 and the main rear housing 12, the post 1123 is also located between the first portion 112 and the mounting plate 122. The boss 1123 may have a threaded hole therein for receiving a screw. One or more snap features 1124 may also be provided at the lower edge of the inner surface 1122 of the first portion 112. The first portion 112 may also extend upward from the outer side surface 1112 of the top plate 111 to form a ridge 1125 that matches the shape of the outer side surface 1112, i.e., in a direction extending away from the bottom plate 121 (see fig. 8) from the top plate 111. The height of the ridge portion 1125 may be equivalent to the thickness of the main trim piece 15 so that the main trim piece 15 can be placed in the space defined by the top panel 111 and the ridge portion 1125 with the rearward side of the ridge portion 1125 in contact with the forward side of the main trim piece 15. The ridge portion 1125 may also be disposed around the periphery of the main housing garnish 15. The connecting portion 114 extends forward from the first portion 112, i.e. in a direction away from the protruding pillar 1123, and a step is formed on the connecting portion 114, and one or more locking structures 1141 may be disposed on the step. In one embodiment, each of the snap structures 1141 is a groove. The snap structure 1141 may also be a bump, a hook, a slot, etc. The connecting portion 114 may be provided with guide structures 1142, such as horizontally extending bosses, on both sides thereof. These guide structures 1142 and snap structures 1141 are used to mate and connect with the face shield 13.

As shown in fig. 6 and 7, the second portion 113 is provided on the front side of the top plate 111, and is connected to the front end of the connecting portion 114 in accordance with the position of the eyes of the user. The width of the second portion 113 in the up-down direction at the middle position may be wider than the width at the both-side connecting portion 114. The second portion 113 may have a central through hole 1131 and two through holes 1132 located at two sides of the through hole 1131, for passing through external light received by the camera.

As shown in fig. 7, one or more reinforcing ribs 115 may be further provided at the junction of the top plate 111 and the second portion 113 to enhance the connection between the second portion 113 and the top plate 111.

The main rear shell 12 of the first housing assembly 10

Referring to fig. 8 and 9, the main rear case 12 may include a bottom plate 121 vertically opposite to the top plate 111 of the main front case 11 and a mounting plate 122 front-back opposite to the first side plate of the main front case 11, and the mounting plate 122 may also be referred to as a second side plate. The main rear housing 12 may be substantially L-shaped in cross-section, and when mated with the inverted L-shape of the main front housing 11, forms a receiving chamber 17 (see fig. 22). The main back housing 12 may be an integrally injection molded part to increase the structural strength of the main back housing 12. One or more reinforcing ribs 123 may also be provided at the connection of the base plate 121 and the mounting plate 122 to enhance the connection between the base plate 121 and the mounting plate 122.

The bottom plate 121 may have a crescent shape substantially the same as the top plate 111, and two rectangular through holes 1211 and 1212 are symmetrically formed in the bottom plate 121 for the waveguide 63 (see fig. 14) of the optical-mechanical assembly 60 to pass through from above. One or more snap features 1214 are also provided on the upper surface 1213 of the base plate 121 at an edge remote from the mounting plate 122 to engage with the snap features 1124 of the first portion 112 of the main front housing 11. One or more speaker sound outlet holes 1215 may be further provided at the middle positions of both sides of the bottom plate 121, that is, a first set of speaker sound outlet holes including the one or more speaker sound outlet holes 1215 are provided at the middle position of one side of the bottom plate 121, and a second set of speaker sound outlet holes including the one or more speaker sound outlet holes 1215 are provided at the middle position of the other side of the bottom plate 121. When the user wears the head-mounted device 100, the speaker sound outlet 1215 is close to the user's ear, so that the user can conveniently hear the sound played by the speaker provided in the head-mounted device 100. A first magnet 1216 may also be provided in the middle of the bottom plate 121 near the mounting plate 122. Two grooves 1217 may also be provided on both sides of the bottom plate 121, opposite the lower surface of the top plate 111, corresponding to the first magnet 1216, the two grooves 1217 being located on the side of the rear cover 14, opposite the face mask 13. The first and second sets of speaker sound outlet holes may be located on both sides of the two grooves 1217, respectively, and the first and second sets of speaker sound outlet holes are located farther from the rear cover 14 than the two grooves 1217.

One or more channels 1240 for voice input may also be provided in the bottom plate 121. These channels 1240 may be formed in the middle of the bottom plate 121 and near the mounting plate 122. For example, a channel 1240 is provided at a left side position of the first magnet 1216 and a channel 1240 is provided at a right side position of the first magnet 1216. The inlet 1241 of each channel 1240 is located on the lower surface of the base plate 121, i.e., on the bottom surface of the housing 10. The inlets 1241 of both channels 1240 may be adjacent the mounting plate 122. The outlet 1242 of the channel 1240 is located on the upper surface 1213 of the base plate 121. These channels 1240 may be referred to as microphone apertures for transmitting sound into a microphone component 92 (see fig. 18) disposed within the head-mounted device 100, thereby gathering sound data of the user and/or the external environment by the microphone component 92.

In one embodiment, the distance between two channels 1160 is greater than the distance between two channels 1240; and, a distance between one of the channels 1160 and one of the channels 1240 adjacent thereto is equal to a distance between the other channel 1160 and the other channel 1240 adjacent thereto.

The mounting plate 122 extends upwardly from the base plate 121, and the mounting plate 122 may have an arc shape that substantially matches the contour of a user's forehead. Through holes 1221 are formed in both sides of the mounting plate 122 for screws to pass through. One or more snap features 1223 may be provided at the upper edge of the outer side 1222 of the mounting plate 122. In one embodiment, each of the snap structures 1223 is a hook to engage with a snap structure 1116, such as a hook, of the top plate 111 of the main front housing 11.

When the main front shell 11 and the main rear shell 12 are buckled, the mounting plate 122 is connected with the top plate 111 through the buckling structures 1223 and 1116; the first portion 112 and the base plate 121 are connected by a snap feature 1124 and a snap feature 1214. Through buckle structure 1223 and buckle structure 1116 and buckle structure 1124 and buckle structure 1214's block connection, can play later stage maintenance detachable effect, also can avoid using too much screw to assemble and increase the weight of product. In addition, in order to enhance the connection between the main front case 11 and the main rear case 12, the top plate 111 and the bottom plate 121 may be fixed by screws, bolts, or the like.

The snap structures 1116 and 1223 may constitute a first connection mechanism disposed between the top plate 111 and the mounting plate 122, and the snap structures 1124 and 1214 may constitute a second connection mechanism disposed between the bottom plate 121 and the first side plate, the first and second connection mechanisms causing the main front case 11 and the main rear case 12 to cooperate to form an accommodation chamber 17 for accommodating a host of the head-mounted device 100. In other embodiments, the first connection mechanism may be a threaded connection or an adhesive connection and the second connection mechanism may be a threaded connection or an adhesive connection.

It should be noted that when the first housing assembly 10 is described separately (i.e., when it is not described in conjunction with the second housing assembly 30), the main front housing 11 thereof may also be referred to as a first housing, and the main rear housing 12 thereof may also be referred to as a second housing.

Face shield 13 of first shell assembly 10

Referring to fig. 10 and 11, the face mask 13 may be translucent and may include a mask portion 131, a mounting portion 132, and a lens assembly 133. The mask portion 131 includes a first mask portion 1311, a second mask portion 1312 that are bilaterally symmetrical, and a connecting portion 1313 that is located midway between the first mask portion 1311 and the second mask portion 1312.

The first and second mask portions 1311, 1312 have optical transparency characteristics, and satisfy light transmission performance at least at two through holes 1132 corresponding to the second portion 113 of the main front case 11 to achieve the following: external light can pass through the first mask portion 1311 and the second mask portion 1312, and objects inside the mask 13 cannot be seen from the outside by human eyes. For example, the transmittance of the face mask 13 is reduced by processing the face mask 13 to achieve a semitransparent effect, so that human eyes cannot see the structures inside the face mask 13, but the camera assembly 70 can receive external light from the inside of the face mask 13, so that objects outside and the like can be imaged. The material of the mask 13 may include plastic or hardware.

The connecting portion 1313 has a through hole 1314 formed at a position corresponding to the through hole 1131 of the second portion 113. The mounting portion 132 extends rearward from the edge of the mask portion 131, that is, toward the main front case 11. The edge of the mounting portion 132 remote from the visor portion 131 may be provided with one or more snap features 1321, such as a catch or boss. The inner surface of the mounting portion 132 on both sides may be provided with one or more guide structures 1322, such as horizontally extending bosses or steps. The fastening structures 1321 and the guiding structures 1322 are respectively configured to be coupled with the fastening structures 1141 and the guiding structures 1142 of the connecting portion 114 of the main front shell 11, so as to mount the mask 13 on the main front shell 11, for example, to make the first mounting portion 132 be attached to the connecting portion 114 of the first side plate. The cover area of the face mask 13 is larger than that of the main front shell 11 when viewed from directly in front of the face mask 13. Thus, when the face mask 13 is mounted on the main front shell 11, only the upper portion of the face mask 13 is in abutting connection with and covers the first side plate of the main front shell 11 (for example, the upper portion of the face mask portion 131 covers the second portion 113 of the first side plate), and the lower portion of the face mask 13 is lower than the main front shell 11, i.e., extends downward beyond the main front shell 11 (see fig. 4), and correspondingly beyond the bottom plate 121. A protective space is formed between the rear cover 14 and the lower portion of the face mask 13 to protect the waveguide piece 63 therebetween. The upper portion of the face mask 13 may be the upper half of the face mask 13 and the lower portion of the face mask 13 may be the lower half of the face mask 13.

The snap structure 1321 of the mask 13 and the snap structure 1141 of the connecting portion 114 may form a connecting structure between the edge of the first mounting portion 132 away from the mask portion 131 and the connecting portion 114, and the snap structure 1321 is in snap connection with the snap structure 1141. The guide structure 1322 of the mask 13 and the guide structure 1142 of the connecting portion 114 may constitute a guide structure between the surface of the first mounting portion 132 facing the connecting portion 114 and the connecting portion 114, and the guide structure 1322 and the guide structure 1142 are slidably engaged.

The lens assembly 133 may be inserted into the through-hole 1314. The lens assembly 133 may include a lens holder 1331, and first and second lenses 1332 and 1333 mounted on the lens holder 1331. Lens holder 1331 may include a first through-hole 1334, a second through-hole 1335, and a third through-hole 1336. The first through hole 1334 may be centrally disposed, and the second through hole 1335 and the third through hole 1336 are located at both sides of the first through hole 1334. The first lens 1332 may be inserted and fixed in the first through hole 1334 from the rear. The second lens 1333 may include two lens portions 1338 corresponding to the second and third through holes 1335 and 1336, respectively, and a through hole 1339 located therebetween. The second lens 1333 may be bonded to the front surface of the lens holder 1331 by an adhesive 134. The lens holder 1331 may also have an annular flange 1337 on the front surface thereof surrounding the first through-hole 1334, the second through-hole 1335 and the third through-hole 1336. The annular flange 1337 may have a protruding length equal to the thickness of the second lens 1333, such that the second lens 1333 may be received within the space enclosed by the annular flange 1337. The lens holder 1331 may be coupled to the rear surface of the connection portion 1313 by an adhesive 135, and may have the annular flange 1337 inserted into the through hole 1314. The adhesive members 134 and 135 may be double-sided tape or the like.

In the assembled lens assembly 133, the first lens 1332 is inserted in the first through hole 1334 and is opposite to the through hole 1339; the two lens portions 1338 are opposed to the second through hole 1335 and the third through hole 1336, respectively.

Rear cover 14 of first housing assembly 10

Referring to fig. 12, the rear cover 14 may be transparent and may include a light-transmitting portion 141 and a mounting portion 142. The light-transmitting part 141 has a light-transmitting property by optical characteristics, so that light emitted from the optical engine assembly 60 can be incident to the eyes of a user through the light-transmitting part 141. The translucent portion 141 may be disposed substantially parallel to the mask portion 131 of the mask 13. The mounting portion 142 extends backward from the edge of the translucent portion 141 except the upper edge, i.e. extends in a direction away from the mask 13, and a flange 1421 is formed outward at the edge of the mounting portion 142 away from the translucent portion 141. Referring to fig. 5, the rear cover 14 is assembled with the lower portion of the mask 13 and is correspondingly located below the bottom plate 121; wherein the rear cover 14 can be approached toward the face mask 13 so that the translucent portion 141 and the mounting portion 142 are inserted into the lower portion of the face mask 13 until the flange 1421 abuts against the end surface of the mounting portion 132 of the face mask 13 (see also fig. 20). The rear cover 14 may be further coated with an adhesive to reinforce the connection at the portion contacting the face mask 13 and the main rear case 12. Since the waveguide 63 (see fig. 14) of the opto-mechanical assembly 60 generally comprises a glass material, which may be fragile, by protecting the waveguide 63 from both the outside and the inside with the face shield 13 and the back cover 14, safety is increased, avoiding injury to the eyes of the user due to accidental crushing of the glass material. In addition, the rear cover 14 may be fully transparent, and have a higher light transmittance than a general transparent material, so that a user can clearly see the picture displayed by the waveguide sheet 63 when wearing the head-mounted device 100.

The main housing trim 15 of the first housing component 10

Referring to fig. 13, the main decorative piece 15 may be crescent-shaped, and the top surface 151 may be streamlined or smooth to enhance the aesthetic appearance of the product. The main case garnish 15 may be disposed on the top plate 111 to cover the top plate 111, that is, the top of the main front case 11, and thus the main case garnish 15 may also be referred to as a cover plate; also, the arcs of the two opposite sides of the cover plate 15 are respectively the same as the arc of the inner side 1111 of the top plate 111 and the arc of the outer side 1112 of the top plate 111. Referring to fig. 5, one or more key holes 152 may be formed on both sides of the main housing decoration 15, and the number of the key holes 152 is the same as that of the side keys 16; for example, two key holes 152 are provided at the front left of the body garnish 15, and two key holes 152 are provided at the front right of the body garnish 15. These key holes 152 are provided in vertical correspondence with the housing portions 1113 in the top plate 111 of the main front case 11. The four side keys 16 are respectively disposed above the receiving portions 1113 of the top plate 111, and partially protrude out of the main casing decorative part 15 through the key holes 152 of the main casing decorative part 15, so that a user can press the side keys 16 to adjust various parameters of the head-mounted device 100. Since the four side keys 16 are located at substantially the left and right front positions of the first casing assembly 10, the operation and use by the user are facilitated. A recess 154 is further formed in the central portion of the inner side 153 of the body trim 15. One or more studs 156 project downwardly from the lower surface 155 of the main trim piece 15, and the studs 156 may have threaded holes. As described above, the main housing garnish 15 is for placement in the space defined by the ceiling 111 and the ridge 1125 of the main front housing 11; wherein, the convex pillar 156 of the main case ornament 15 can pass through the through hole 1114 of the top plate 111 to be fixed to the top plate 111 of the main front case 11.

Referring back to fig. 4 and 5, when the first housing assembly 10 is assembled, the main front housing 11 and the main rear housing 12 are assembled together by the snap structures 1124, 1116, 1214 and 1223 on the main front housing. The mask 13 can be covered in front of the main front shell 11 by engaging the engaging structure 1321 with the engaging structure 1141. The rear cover 14 may be approached toward the face mask 13 and inserted into the lower portion of the face mask 13. The main housing decorative member 15 is mounted on the top of the main front housing 11.

Opto-mechanical assembly 60

Referring to fig. 14, a perspective view of the opto-mechanical assembly 60 of the head-mounted device 100 according to the embodiment of the present application is shown. The opto-mechanical assembly 60 may include an opto-mechanical mount 61, an opto-mechanical 62, and a waveguide 63.

The mount 61 may include a top plate 611, a side plate 612 extending from one side of the top plate 611, and two legs 613 extending from the top plate 611 and located on either side of the top plate 611 and the side plate 612.

The top plate 611 may be horizontally disposed. It should be noted that the top plate 611 does not need to be a continuous flat plate, and may be provided with a recess at one or more positions to reduce the weight of the structure while satisfying the supporting strength. One or more through holes 6111 may be formed in the top plate 611 for mounting other components. These through holes 6111 may or may not have threads therein. One or more strip-shaped through holes 6112 may be formed in the front portion of the top plate 611 for the FPC to pass through. The side plates 612 extend downward from the front edge of the top plate 611, and the two legs 613 are respectively located at the left and right sides of the top plate 611 and extend downward. A through hole 6121 and a through hole 6122 are formed in the middle of the side plate 612, two through holes, namely the through hole 6125 and the through hole 6126, are formed in the two sides of the middle of the side plate 612 respectively, and the through holes 6121, 6122, 6125 and 6126 can be used for inserting the camera assembly 70. The through hole 6121 and the through hole 6122 are adjacently arranged, and the distance from the through hole 6121 to the through hole 6126 can be equal to the distance from the through hole 6122 to the through hole 6125. The through hole 6121 and the through hole 6122 correspond to a central through hole 1131 formed in the second portion 113 of the main front shell 11 as a whole, the through hole 6125 and the through hole 6126 correspond to two through holes 1132 formed in the second portion 113 of the main front shell 11 respectively, and the through holes 1131 and 1132 are used for allowing external light rays to be received by the camera shooting assembly to pass through. The lower end of each leg 613 may be provided with a through hole 6131.

The number of the optical engines 62 is two, and the number of the waveguide pieces 63 is also two. The two optical machines 62 and the two waveguide pieces 63 may be disposed on a connecting body 64, that is, the optical machines 62 and the waveguide pieces 63 are held by the connecting body 64. The connecting body 64 may have one or more through holes 641. These through holes 641 may or may not have threads therein. The two optical machines 62 may be symmetrically disposed within the receiving chamber 17.

A pad 65 may also be provided below the connector 64. The gasket 65 may be fitted over the waveguide plate 63 and abut against the lower surface of the connecting body 64. The gasket 65 is used to be clamped between the connecting body 64 and the bottom plate 121 of the main rear case 12 during assembly, so as to prevent the connecting body 64 from being in hard contact with the main rear case 12, thereby achieving a protective effect. The liner 65 may be a compressible or resilient material such as flexible rubber, foam, or the like.

Each light engine 62 may also be connected to a heat sink 621 within the containment chamber 17 to thermally conductively couple and dissipate heat from one or more heat sources 622, such as LED lights, of the light engine 62. In an embodiment, the heat sink 621 can include a first heat sink portion 6211, a second heat sink portion 6212, and a third heat sink portion 6213. The first and second heat sink portions 6211, 6212 can be connected together, and the top surfaces of the first and second heat sink portions 6211, 6212 can be disposed coplanar, and the third heat sink portion 6213 can extend laterally from the connection of the first and second heat sink portions 6211, 6212. For example, the third heat sink member 6213 can extend perpendicularly from the junction of the first and second heat sink members 6211, 6212. Wherein the second heat sink portion 6212 can be connected to a heat source 622 for heat dissipation; the third heat sink portion 6213 can be connected to another heat source 622 for heat dissipation. The first heat sink portion 6211, the second heat sink portion 6212, and the third heat sink portion 6213 of the heat sink 621 may be provided separately from each other or may be provided as an integral structure for easy assembly; in addition, the heat sink 621 may also extend into the interior space of the opto-mechanical assembly 60 and/or the first housing assembly 10, and may also dissipate more heat generating components simultaneously by contacting other heat generating components. For example, the first heat sink portion 6211 of the heat sink 621 may extend rearwardly for thermally conductive connection with the power FPC 213 (see fig. 28) or the second heat sink 225 (see fig. 33) of the strap assembly 20. At least one of the heat sink 621 and the second heat sink 225 may include a graphite sheet.

Each light engine 62 may be a projector. The light engine 62 provides light to the waveguide 63, which includes information and/or images for providing enhanced viewing of the physical world by a user. Light from the optical engine 62 may be coupled into the waveguide 63, totally internally reflected within the waveguide 63, and then coupled out of the waveguide 63 so that the light may be viewed by a user.

When assembling, screws can be used to pass through the through holes 6111 of the top plate 611 and the through holes 641 of the connecting body 64, so as to fix the optical machine bracket 61, the optical machine 62 and the waveguide piece 63 together. In the assembled opto-mechanical assembly 60, an accommodating space is defined between the connecting body 64 and the side plate 612 of the opto-mechanical bracket 61, and part of the image pickup assembly 70 is accommodated therein.

Referring again to fig. 15, there is shown another perspective view of the opto-mechanical mount 61 of the opto-mechanical assembly 60 of fig. 14. As shown in fig. 15, a slot 6123 and an abutting portion 6124 are respectively disposed on the rear side of the side plate 612 and on the two sides of the middle position where the through holes 6121 and 6122 are defined, and the slot 6123 may be higher than the abutting portion 6124. The abutting portion 6124 may have a flat surface and may have a threaded hole. A slot 6127 is disposed on the rear side of the side plate 612 and on one side of the position where the through hole 6125 is defined, and a slot 6128 and an abutting portion 6129 are disposed on the other side of the position. The slot 6128 and abutment 6129 can be directly adjacent. The top end of the slot 6127 is flush with the top end of the slot 6128, but the length of the downward extension of the slot 6127 is greater than the length of the downward extension of the slot 6128. The abutting portion 6129 may have a flat surface and may have a threaded hole. The position of the slot 6128 can be higher than the position of the abutting portion 6129. The rear side surface of the side plate 612 is provided with a slot and an abutting portion, which are the same as or similar to the slot 6127, the slot 6128 and the abutting portion 6129, at a position where the through hole 6126 is defined, and the description thereof is omitted here.

Camera assembly 70

Referring to fig. 16, a camera assembly 70 of the head mounted device 100 according to the embodiment of the present application is shown. The camera module 70 is mounted on the optical engine bracket 61 of the optical engine module 60 and may include a Time of flight (TOF) camera 71, an RGB camera 72, two fisheye cameras 73, a first camera bracket 74 for fixing the TOF camera 71 and the RGB camera 72, and two second camera brackets 75 for fixing the two fisheye cameras 73 respectively.

The TOF camera 71 may include a light emitting module 711, a light sensing receiving module 712, an FPC 713, and a heat sink 714. The light emitting module 711 and the light sensing receiving module 712 are both connected to the FPC 713. The light emitting module 711 has a front end portion, which may also serve as a front end portion of the TOF camera 71. The heat sink 714 is connected to the FPC 713, for example, attached to the rear surface of the FPC 713 to dissipate heat. The heat sink 714 has a back side that may also serve as a back side of the TOF camera 71. When the TOF camera 71 works, the light emitting module 711 is configured to emit a modulated light beam, the light beam is reflected by a target object and then received by the light receiving module 712, and the light receiving module 712 can obtain the flight time of the light beam in space through demodulation, so as to calculate the distance of the corresponding target object. Thus, with the TOF camera 71, the shape and model of a room can be modeled when the user wears the head-mounted device 100 around, for example, the environment of the room; that is, the shape and model of the room in which the user is located can be determined by measuring the distance from each point to the head-mounted device 100 worn by the user, thereby constructing a scene.

The RGB camera 72, which may be used to capture two-dimensional color images, color differences in captured images, etc., is connected to the TOF camera 71 and may be secured by a first camera mount 74. The RGB camera 72 may include a camera main body 721 and an FPC 722. The camera main body 721 has a front end portion, which may also be the front end portion of the RGB camera 72. The camera main body 721 is connected to an FPC 722.FPC 722 and FPC 713 may be connected together at the upper end. The heat sink 714 may also be attached to the FPC 722, for example, to the rear surface of the FPC 722 for heat dissipation. The rear side of the heat sink 714 also serves as the rear side of the RGB camera 72.

The TOF camera 71 and the RGB camera 72 may be further provided with a gasket 76 at the front end thereof. The gasket 76 is used for being clamped between the TOF camera 71 and the RGB camera 72 and the side plate 612 of the optical engine bracket 61 during assembly, so that the TOF camera 71 and the RGB camera 72 are prevented from being in hard contact with the optical engine bracket 61, and a protection effect is achieved. The pad 76 may be a compressible or resilient material such as flexible rubber, foam, or the like.

Each fisheye camera 73 may include a camera body 731, a camera mounting plate 732, and an FPC 733. The camera body 731 has a front end portion, and the front end portion may be a front end portion of the fisheye camera 73. The camera main body 731 is connected to an FPC 733 and mounted on the camera mounting plate 732. The FPC 733 has a rear side surface, and the camera mounting plate 732 also has a rear side surface; the FPC 733 or camera mounting plate 732 may be disposed adjacent to the second camera bracket 75, with its respective rear side serving as the rear side of the fisheye camera 73. The camera mounting plate 732 may include a main body portion 7321, a first mating portion 7322, and a second mating portion 7323. The main body part 7321 is used to carry the camera main body 731. For example, the camera main body 731 may be fixed on the main body portion 7321 by a dispensing process or screws. The first and second mating parts 7322 and 7323 are respectively located at both sides of the main body part 7321. In the up-down direction, the first mating part 7322 and the second mating part 7323 may be located at the upper middle position of the main body part 7321, that is, the connection position of the first mating part 7322 and the second mating part 7323 with the main body part 7321 is close to the top of the main body part 7321. The side of the first mating part 7322 may include a semi-cylindrical portion, and the side of the second mating part 7323 may also include a semi-cylindrical portion.

In one embodiment, the TOF camera 71 and the RGB camera 72 are disposed adjacent to each other and receive external light through the first through hole 1131, and the two fisheye cameras 73 are disposed at two sides of the TOF camera 71 and the RGB camera 72. The two fisheye cameras 73 are mainly used for matching images. Of course, the position arrangement of the cameras is not limited to this, and can be adjusted according to actual needs. In addition, the types of the cameras are not limited to the above, and different types of cameras can be selected according to actual needs.

Different cameras and different arrangement positions are adopted, so that the imaging principle and the imaging effect are different. For example, four cameras, TOF camera 71, RGB camera 72 and two fisheye cameras 73 may complement each other; the fisheye camera 73 has a large shooting angle, and can be a wide-angle camera, but the resolution ratio can be relatively low. The resolution of the RGB camera 72 may be relatively high, but the shooting angle thereof may be relatively small, and by combining the RGB camera 72 and the fisheye camera 73, a relatively clear image with a relatively large shooting angle can be formed.

The first camera mount 74 is located behind the TOF camera 71 and the RGB camera 72 to mount the two TOF cameras 71 and the RGB camera 72 on the opto-mechanical mount 61 of the opto-mechanical assembly 60. The first camera bracket 74 may include an intermediate portion 741, a plug portion 742, and a fixing portion 743. The middle portion 741 has a pressing surface facing the TOF camera 71 and the RGB camera 72, and the pressing surface may include two flat surfaces, i.e., a first flat surface 7411 and a second flat surface 7412. The insertion part 742 and the fixing part 743 are respectively located at both sides of the middle part 741; in the vertical direction, the inserting part 742 and the fixing part 743 may be located at different heights on both sides of the middle part 741, for example, the inserting part 742 may be located higher than the fixing part 743. The sides of the plug portion 742 may include a semi-cylindrical portion to facilitate rotation within the slot 6123. The fixing portion 743 has a through hole 744.

The two second camera supports 75 are symmetrically disposed and located behind the two fisheye cameras 73 respectively. Each second camera mount 75 can include a middle portion 751, a mating portion 752, and a fixing portion 753. The intermediate portion 751 is connected between the insertion portion 752 and the fixing portion 753, and is disposed away from the fisheye camera 73 from the insertion portion 752 and the fixing portion 753. The insertion portion 752 and the fixing portion 753 are respectively positioned on both sides of the intermediate portion 751. In the up-down direction, the insertion portion 752 and the fixing portion 753 may be located at the same or different height positions on both sides of the middle portion 751; for example, the mating section 752 may be positioned at or below the middle of one side of the middle section 751, i.e., the connection between the mating section 752 and the middle section 751 is between the top and bottom of the middle section 751 or near the bottom of the middle section 751; the fixing portion 753 may be positioned at an intermediate position on the other side of the intermediate portion 751. The sides of the insert 752 may include a semi-cylindrical portion to facilitate rotation within the slot 6127. The fixing portion 753 has a through hole 754.

As shown in fig. 15, 16, and 17, when the TOF camera 71 and the RGB camera 72 are assembled to the carriage assembly 60, the TOF camera 71 and the RGB camera 72 are fixed to the carriage 61 of the carriage assembly 60 by the first camera holder 74. Specifically, the TOF camera 71 and the RGB camera 72 may be inserted into the through hole 6121 and the through hole 6122 of the opto-mechanical mount 61 from the rear, the insertion part 742 is inserted into the slot 6123 of the opto-mechanical mount 61, the fixing part 743 is pressed against the abutting part 6124, a screw is used to pass through the through hole 744 of the fixing part 743, and then screwed into the threaded hole of the abutting part 6124 of the opto-mechanical mount 61, so that the TOF camera 71 and the RGB camera 72 are mounted on the opto-mechanical mount 61, and the middle part 741 is pressed on the rear side surfaces of the TOF camera 71 and the RGB camera 72. In the assembled state of the camera assembly 70 and the opto-mechanical assembly 60 in the first housing assembly 10, the front end portion of the photosensitive receiving module 712 of the TOF camera 71 is inserted into the through hole 6121 of the opto-mechanical bracket 61. The front end of the photoreception receiving module 712 also corresponds to the through hole 1131 of the second part 113 of the main front case 11, and to one lens part 1338 of the second lens 1333 of the lens assembly 133. The front end portion of the light emitting module 711 of the TOF camera 71 is inserted into the through hole 6121 of the optical engine bracket 61. The front end of the light emitting module 711 also corresponds to the through hole 1131 of the second portion 113 of the main front shell 11 and to the first lens 1332 of the lens assembly 133. The front end of the RGB camera 72 is inserted into the through hole 6122 of the optical engine bracket 61. The front end of the RGB camera 72 also corresponds to the through hole 1131 of the second part 113 of the main front case 11 and to the other lens part 1338 of the second lens 1333 of the lens assembly 133.

When the fisheye cameras 73 are assembled to the optical-mechanical assembly 60, the two fisheye cameras 73 are respectively fixed on the side plates 612 of the optical-mechanical support 61 of the optical-mechanical assembly 60 through the two second camera supports 75. Specifically, the camera main body 731 of each fisheye camera 73 may be inserted into the through hole 6125 or 6126 of the optical engine mount 61 from the rear, the first inserting portion 7322 and the second inserting portion 7323 of the camera mounting plate 732 may be inserted into the slot 6127 and the slot 6128 of the optical engine mount 61, respectively and simultaneously, and then the camera main body 731 and the camera mounting plate 732 may be fixed together by screws. Subsequently, the inserting part 752 of the second camera holder 75 can be inserted into the slot 6127 of the optical engine holder 61, and a screw can be used to pass through the through hole 754 of the fixing part 753 and then screwed into the threaded hole of the abutting part 6129 of the optical engine holder 61, so that the fisheye camera 73 can be mounted on the optical engine holder 61, and the middle part 751 can be pressed on the rear side surface of the fisheye camera 73. The plug part 752 of the second camera bracket 75 and the first plug part 7322 of the camera mounting plate 732 are in abutting contact with each other in the slot 6127.

Fix TOF camera 71, RGB camera 72 and fisheye camera 73 through above-mentioned structure, can save some set screws for assembly efficiency improves.

Since the TOF camera 71, the RGB camera 72, and the fisheye camera 73 are all mounted on the opto-mechanical mount 61, the opto-mechanical mount 61 may also be referred to as a mounting base.

In an assembled state of the camera assembly 70 and the optical-mechanical assembly 60 in the first housing assembly 10, a front end portion of one of the fisheye cameras 73 is inserted into the through hole 6125 of the optical-mechanical bracket 61 and corresponds to one of the through holes 1132 of the second portion 113 of the main front shell 11 to receive external light; the front end of the other fisheye camera 73 is inserted into the through hole 6126 of the optical engine bracket 61 and corresponds to the other through hole 1132 of the second part 113 of the main front shell 11 to receive the external light.

In addition, the upper end of the FPC 722 and the FPC 713 connected together may be exposed to the top of the top plate 611 through one elongated through hole 6112 of the top plate 611. Similarly, the FPCs 733 of the two fisheye cameras 73 may be exposed to the top of the top plate 611 through the elongated through holes 6112 on both sides of the top plate 611, respectively.

Mainboard 80, speaker assembly 91 and microphone assembly 92

Referring to fig. 18 and 19, exploded perspective views of the main board 80, the speaker assembly 91 and the microphone assembly 92 of the head-mounted device 100 according to the embodiment of the present application are shown.

The motherboard 80 is mounted on the opto-mechanical assembly 60, which may include a PCB (Printed Circuit Board, herein collectively referred to as PCB) 81, and one or more chips 82, one or more protective covers 83, and one or more heat sinks 84 disposed on the PCB 81.

The PCB81 may be a substrate having printed wiring, and may serve as a carrier for electrical connection of electronic components. The chips 82 may be mounted on the PCB81, wherein some of the chips 82 may be covered by one or more protective covers 83 for protection. The heat sink 84 may be provided on an outer surface of the protective cover 83 to dissipate heat. The fins 84 may be graphite fins.

The left and right sides of the PCB81 may also be connected to two key FPCs 162, respectively. Each key FPC 162 may include a connection section 1621, a key section 1622, and a bending section 1623 disposed between the connection section 1621 and the key section 1622. The connection segment 1621 is used to connect with the PCB 81. When the main board 80 is assembled in the first housing assembly 10, each key FPC 162 may be folded upward to allow the key segment 1622 to be disposed in the receiving portion 1113 of the top plate 111 of the main front housing 11, so that the key segment 1622 can be pressed by the boss 161 below the side key 16.

The left side of the PCB81 may also be connected to an optical engine FPC 623. The light machine FPC 623 is used to connect the left light machine 62 to the PCB 81. Similarly, an optical engine FPC (not shown) may be connected to the right side of the PCB81 to connect the right optical engine 62 to the PCB 81.

As shown in fig. 18, the speaker assembly 91 may include a first speaker 911 and a second speaker 913. The first speaker 911 may be located on the left side of the motherboard 80 and the second speaker 913 may be located on the right side of the motherboard 80. In the assembled configuration, the first speaker 911 may be connected to the left end of the PCB81 and located below the left key FPC 162; the second speaker 913 may be connected to a right end of the PCB81 and located under the key FPC 162 on the right side. The first speaker 911 may extend backward from the left end of the PCB81 and the second speaker 913 may extend backward from the right end of the PCB 81.

In an embodiment, the receiving chamber 17 defined by the first housing assembly 10 may include a first chamber for receiving the main board 80 and second and third chambers located on opposite sides of the first chamber. The first speaker 911 may be located in the second chamber and connected to one end of the main board 80 in a contact manner, and the second speaker 913 may be located in the third chamber and connected to the other end of the main board 80 in a contact manner.

The second speaker 913 may include a cavity case 9131 and a speaker body 9132 disposed in the cavity case 9131, where the cavity case 9131 is used to provide a certain cavity, so that the sound emitted from the speaker body 9132 can swirl inside the cavity case 9131, thereby providing a good sound effect for the user to hear. The first speaker 911 may have the same structure as the second speaker 913, i.e., the first speaker 911 may include a cavity case 9111 and a speaker body 9112 (see fig. 19) placed inside the cavity case 9111. The first speaker 911 may be mounted at the left rear end of the main board 80 and may be connected to the main board 80 through a wire or an FPC (not shown). Similarly, the second speaker 913 may be mounted at the rear end of the right side of the main board 80 and may be connected to the main board 80 through a wire or an FPC (not shown). It is noted that when the main board 80 and the speaker assembly 91 are assembled in the first housing assembly 10, the first speaker 911 and the second speaker 913 are located at two corner positions of the first housing assembly 10, respectively; the first speaker 911 and the second speaker 913 correspond to speaker sound outlet holes 1215 formed in the bottom plate 121 of the first housing member 10, and are used for outputting sound emitted from the first speaker 911 and the second speaker 913. The first speaker 911 and the second speaker 913 may also be located, for example, at positions below the corresponding side key 16, e.g., the first speaker 911 corresponds to at least one side key 16 in a direction perpendicular to the top plate 111, and the second speaker 913 corresponds to at least one side key 16 in a direction perpendicular to the top plate 111. Since the space of the two corner positions of the first housing member 10 is utilized, the structure is made compact and the sound effect can be improved.

In one embodiment, the microphone assembly 92 may include a first microphone 921, a second microphone 923, a third microphone 925, and a fourth microphone 927, all disposed within the receiving chamber 17.

The first microphone 921 may be connected to the PCB81 through a power FPC 213 (see fig. 28), and the second microphone 923 may be connected to the PCB81 through an FPC 924. In one embodiment, the first microphone 921 may be connected to the PCB81 through a wire or a separate FPC. Wherein, the first microphone 921 and the second microphone 923 may be respectively disposed at two sides of the PCB 81; for example, when the main board 80 is mounted in the first housing assembly 10, the first microphone 921 corresponds to an outlet 1162 of a passage 1160 at a left front position of the first portion 112 of the main front case 11 to receive external sounds through the passage 1160, and the second microphone 923 corresponds to an outlet 1162 of a passage 1160 at a right front position of the first portion 112 of the main front case 11 to receive external sounds through the passage 1160. The first microphone 921 may also be supported by or secured to the first speaker 911. The second microphone 923 may also be supported by or secured to the second speaker 913.

The third and fourth microphones 925 and 927 may be disposed at a lower position of the middle portion of the PCB81 and correspond to the outlets 1242 of the two passages 1240 on the bottom plate 121 of the main rear case 12, respectively, to receive external sounds through the two passages 1240, respectively. Since the third and fourth microphones 925 and 927 may be positioned lower than the PCB81, a support 929 may be provided between the PCB81 and the third and fourth microphones 925 and 927. That is, the third microphone 925 and the fourth microphone 927 may be supported by the support 929, and the support 929 may be fixed on the PCB 81. The third microphone 925 can be connected to the PCB81 through an FPC 926, and the fourth microphone 927 can be connected to the PCB81 through an FPC 928. In one embodiment, the FPCs 926 and 928 may be merged with the FPC 713 of the camera assembly 70 before being connected to the PCB 81. In other embodiments, the FPC 926 and the FPC 928 may be connected to the PCB81 separately, or the FPC 926 and the FPC 928 may be joined and then connected to the PCB 81.

By arranging the microphone assemblies 92 such that they interfere less with each other, the directivity differs more.

Vision adjusting glasses 93

Referring to fig. 20, the first housing assembly 10 of the head-mounted device 100 of the embodiment of the present application is shown in a fitting relationship with the vision adjusting glasses 93. The vision adjustment glasses 93 may include a frame 931, a first lens 932, a second lens 933, and a second magnet 934. The first lens 932 is a left-eye lens, the second lens 933 is a right-eye lens 933, and the first and second lenses 932, 933 are mounted on the frame 931. The second magnet 934 is mounted at an intermediate position above the mirror frame 931 to correspond to and attract the first magnet 1216 (see fig. 8) on the main back case 12. Two protrusions 935 may also be provided on the left and right sides of the second magnet 934 above the frame 931. The two protrusions 935 are provided to correspond to the two grooves 1217 (see fig. 9) on the main rear case 12, i.e., to be inserted into the two grooves 1217, respectively.

The vision adjustment spectacles 93 are removably mounted on the first housing assembly 10 and, in use, are positioned between the eyes of the user and the rear cover 14. Specifically, the two protrusions 935 of the vision adjusting glasses 93 can be inserted into the two grooves 1217 of the main rear case 12, respectively, while the second magnets 934 on the frame 931 are attracted to each other adjacent to the first magnets 1216 on the main rear case 12, thereby attaching the vision adjusting glasses 93 to the first housing assembly 10.

The two grooves 1217 and the two protrusions 935 cooperate to position the vision adjusting eyeglasses 93, and the attraction between the second magnet 934 and the first magnet 1216 fixes the vision adjusting eyeglasses 93. The first lens 932 and the second lens 933 can be near vision lenses, far vision lenses, or the like. The requirements of users with different eyesight can be met by configuring the eyesight adjusting glasses 93 with different degrees. Therefore, the structure can detach the vision adjusting glasses 93, and a user can replace the vision adjusting glasses 93 conveniently according to the vision condition of the user.

Assembly of the front part

Fig. 21 to 23 are schematic diagrams illustrating an assembly relationship of the first housing assembly 10, the optical-mechanical assembly 60, the camera assembly 70, the main board 80 and the speaker assembly 91 of the head-mounted apparatus 100 according to the embodiment of the present disclosure.

As shown in fig. 21 and 22, the TOF camera 71, the RGB camera 72, and the two fisheye cameras 73 of the camera assembly 70 are fixed on the optical engine bracket 61 of the optical engine assembly 60, so as to achieve the assembly of the camera assembly 70 and the optical engine assembly 60.

The main board 80 may be disposed above the top plate 611 of the opto-mechanical support 61 and the main board 80 and the opto-mechanical support 61 are screwed together. Then, as shown in fig. 16, 21 and 22, the upper end formed by connecting the FPC 722 and the FPC 713 together and the upper end of the FPC 733 may be connected to the main board 80 to achieve power-on and/or signal transmission.

As shown in fig. 21 and 23, main front case 11 and main plate 80 may be fixed. For example, as shown in conjunction with FIG. 6, screws are inserted through holes 1114 of main front housing 11 and tightened to main board 80.

Referring to fig. 23, the first speaker 911 and the second speaker 913 may be further fixed to the main front case 11, for example, the top plate 111, by screws after being connected to the main board 80.

As shown in fig. 22 and 23, the two rectangular through holes 1211 and 1212 of the bottom plate 121 of the main rear housing 12 can be aligned with the two waveguide pieces 63 of the opto-mechanical assembly 60, so that the two waveguide pieces 63 of the opto-mechanical assembly 60 extend downward from the accommodating chamber 17 through the two rectangular through holes 1211 and 1212, and then are screwed into the bottom plate 121 of the main rear housing 12 after passing through the through holes 1114 (see fig. 6) of the main front housing 11 and the through holes 6131 (see fig. 14) of the legs 613 of the opto-mechanical support 61 in sequence by screws, thereby fixing the opto-mechanical assembly 60, the camera assembly 70 and the main plate 80 between the main front housing 11 and the main rear housing 12. Additionally, as shown in connection with fig. 21, the main front shell 11 may snap-fit with the snap structure 1223 of the main rear shell 12 via the snap structure 1116, thereby securing the main front shell 11 and the main rear shell 12 together and defining the receiving chamber 17 therebetween. Of course, the connection structure may be further strengthened by more screws, and the optical engine bracket 61 may be fixed to the top plate 111 of the main front housing 11 by a connection structure such as a screw.

As shown in fig. 21 and 23, the side key 16 is disposed in the receiving portion 1113 of the main front case 11, and the main front case 15 is placed on the top plate 111 of the main front case 11, and the side key 16 partially protrudes from the main case 15 through the key hole 152 of the main case 15. The main housing garnish 15 may also be fastened to the main front housing 11 by screws.

As shown in fig. 21 and 23, the face mask 13 can be closed to the connecting portion 114 toward the main front shell 11. The rear cover 14 is movable toward the mask 13 and inserted into a lower portion of the mask 13, so that the two waveguide pieces 63 are received between the mask portion 131 of the mask 13 and the light-transmitting portion 141 of the rear cover 14 to be protected.

As shown in fig. 23, the vision adjusting glasses 93 may be mounted on the main rear case 12 of the first housing assembly 10 and positioned between the eyes of the user and the rear cover 14 in use, depending on the user's needs.

Lace assembly 20

Referring to fig. 24, a perspective assembly view of the strap assembly 20 and the second housing assembly 30 according to the present embodiment is shown. The strap assembly 20 may include two head straps, a first head strap 21 and a second head strap 22.

Referring to fig. 1 and 4, one end of the first headband 21 is connected to the corresponding end of the first shell assembly 10, and the other end of the first headband 21 extends into the corresponding end of the second shell assembly 30 to connect with the tightness adjusting mechanism 40. The second headband 22 may be mounted in a similar manner as the first headband 21.

First headband 21 of strap assembly 20

Referring to fig. 25 and 26, a perspective assembled view and an exploded view of the first headband 21 according to embodiments of the present application are shown. The first headband 21 may include a first headband body 210, a first headband cover 211 that is snap-fit with the first headband body 210, and a first soft strip 212, a power FPC 213, a protective sheet 214, and a first heat sink 215 that are pressed between the first headband body 210 and the first headband cover 211.

The first headband body 210 may be made of a flexible material and may be arbitrarily bent, and may have a substantially elongated shape, and may include a first body portion 2101 and a first mounting portion 2102 extending from one end of the first body portion 2101.

The width of the first main body part 2101 is uniform, a length adjusting hole 2103 is formed in one end, away from the first mounting part 2102, the length adjusting hole 2103 is a strip-shaped through hole, and a first saw tooth 2104 extending in the length direction of the through hole is arranged in the length adjusting hole 2103 of the first main body part 2101 to be matched with the tightness adjusting mechanism 40.

Referring to FIG. 27, an exploded perspective view of the first headband 21 according to the embodiment of the present application is disclosed from another perspective. The first main body 2101 may be provided with an elongated notch having the same shape as the first headband 21 on a side pressed against the first headband cover 211, and the notch may be divided into two parts, i.e., a first notch 2105 and a second notch 2106 connected to the first notch 2105, wherein the depth of the first notch 2105 is the same as the depth of the second notch 2106, but the width of the first notch 2105 is wider than that of the second notch 2106, and the notch extends from a position adjacent to the length adjustment hole 2103 to the position of the first mounting portion 2102. The second groove 2106 is a step-shaped groove, and the outermost step of the groove can be used for accommodating the first soft strip 212. The first body portion 2101 is provided with a first connector 2107 at both side edges of the first recess 2105, the first connector 2107 being a plurality of evenly arranged hooks in one embodiment. The first main body 2101 has a first fixing portion 2108 provided in the first recess 2105. The first fixing portion 2108 may be a plurality of ribs with gradually changing thickness, a top surface of each rib is inclined, and one end of each rib abuts against the first mounting portion 2102.

A plurality of first retaining posts 2109 are provided in the recess of the first main body portion 2101 to fix the power FPC 213, the protective sheet 214, and the first heat sink 215.

The first mounting portion 2102 is provided with two first connection holes 2100. A recess 2102a is formed between the two first connection holes 2100.

Referring to fig. 26, the first headgear cover 211 may be made of a rigid material for engaging with the first headgear body 210 at a side of the first headgear body 210 adjacent to the first mounting portion 2102 and compressing an end of the first flexible strap 212 adjacent to the first mounting portion 2102.

The first headgear cover 211 may include a first body 2111 and a first mounting portion 2112 extending from an end of the first body 2111 distal from the first flexible strap 212.

The first main body 2111 has a uniform width, a shape corresponding to the first main body 2101, and a length shorter than the first main body 2101. First side walls 2116 extend from both side edges of the first body 2111 in the width direction toward the first main body 2101, and second connection members 2117 are provided on the inner side surfaces of both the first side walls 2116. Second connector 2117 cooperates with first connector 2107 to secure first headgear cover 211 to first headgear body 210. The first body 2111 may be provided with a second fixing portion 2114 at an end connected to the first fitting portion 2112, and when the first headgear cover 211 is fastened to the first headgear body 210, the first fixing portion 2108 of the first headgear body 210 cooperates with the second fixing portion 2114 of the first headgear cover 211 to press-fix the power supply FPC 213 and the first heat sink 215 between the first headgear body 210 and the first headgear cover 211; the second fixing portion 2114 may have a structure similar to that of the first fixing portion 2108, and may also be a plurality of ribs with gradually changing thickness, a top surface of each rib is inclined, and one end of each rib abuts against the first assembling portion 2112.

The first fitting portion 2112 has the same shape as the first mounting portion 2102 and is provided with a second coupling hole 2110, and when the first fitting portion 2112 is fitted to the first mounting portion 2102, the first coupling hole 2100 is aligned and communicated with the second coupling hole 2110 to form a through hole at the recess 2102a.

The first flexible strip 212 is made of a flexible material and is optionally bendable, has a substantially elongated shape, has a material corresponding to the first headband body 210, and is adhered to the second recess 2106 of the first headband body 210 by means of glue or the like, so that the outer surface of the first flexible strip 212 is flush with the outer surface of the first headband body 210, i.e., the surface adjacent to the head of the user. The end of the first soft strip 212 is provided with a notch 2120, and when the first soft strip 212 is adhered to the second notch 2106, the first soft strip 212 and the first headband main body 210 form a first through hole together at the notch 2120 to communicate with the second notch 2106 for the power FPC 213 to pass through.

Referring to fig. 25, 26, and 27 together, the power FPC 213 is shaped to fit the first headband body 210, but has a length longer than that of the first headband body 210 and both ends extending beyond both ends of the first headband body 210. The power FPC 213 may include a first electrical connection portion 2132 extending into the first housing assembly 10 to connect with the motherboard 80 and/or the microphone assembly 92, a power FPC neck 2134 engaged in the through hole and connected with the first electrical connection portion 2132, a power FPC main body 2136 fixed in the first and second recesses 2105, 2106, a movable portion 2137 passing through the first through hole and disposed outside the second recess 2106, and a second electrical connection portion 2138 disposed at an end of the movable portion 2137 and connected with the battery 35.

Referring to fig. 28, which is an enlarged view of a portion circled a in fig. 2, it shows a schematic connection diagram of the first electrical connection portion 2132 and the circuit components when the strap assembly 20 is inserted into the first housing assembly 10; the first electric connecting portion 2132 includes a wiring portion 2132a connected to the main board 80 and a wiring portion 2132b connected to the microphone assembly 92; the wiring portion 2132a and the second electrical connection portion 2138 are insertion ports, and are connected by insertion. For example, as shown in fig. 28, the main board 80 is plug-connected to the wiring portion 2132a, and as shown in fig. 29, the second electrical connection portion 2138 is plug-connected to the battery 35.

Referring again to fig. 26 and 27, the power FPC neck 2134 has a narrower width than the adjacent power FPC portions on both sides, such as the power FPC main body 2136; referring to fig. 24, it can be seen that the neck 2134 of the power FPC is just clipped on the first through hole, so as to prevent the power FPC 213 from loosening.

Referring to fig. 26 to 27, the power FPC main body 2136 is provided with a first insertion hole 2135, and when the power FPC main body 2136 is disposed in the first and second notches 2105 and 2106, the power FPC main body 2136 is fixed by disposing the first retention post 2109 in the first insertion hole 2135.

The shape of the protection sheet 214 is adapted to the first and second recesses 2105, 2106 to be received therein, for example, in the first recess 2105 and the innermost recess of the second recess 2106; a plurality of second insertion holes 2140 are formed thereon, and the protection sheet 214 is fixed by placing the first restraint posts 2109 in the second insertion holes 2140. The protection sheet 214 is accommodated in the first and second recesses 2105, 2106 and directly contacts the first main body 2101, so as to prevent the power FPC main body 2136 from directly contacting the first main body 2101.

The first heat sink 215, which is similar in shape to the power FPC 213, is interposed between the first head band cover 211 and the power FPC 213, and may include a first attaching portion 2152 extending into the first housing assembly 10, a first heat sink neck portion 2154 caught in the through hole and connected to the first attaching portion 2152, and a first heat sink main body 2156 fixed in the first recess 2105 and the second recess 2106; for example, as shown in fig. 28, the first fitting portion 2152 is fitted to a side wall of the speaker body 9132.

The first fin neck 2154 is narrower in width than the fin portions on either side thereof, e.g., the first fin body 2156; and with reference to fig. 24, it can be seen that the first heat sink neck 2154 snaps into place over the through hole, preventing the first heat sink 215 from loosening. The first heat sink main body 2156 is provided with a third insertion hole 2158, and when the first heat sink main body 2156 is placed in the first and second grooves 2105, 2106, the first limit post 2109 is placed in the third insertion hole 2158 to fix the first heat sink main body 2156. The first fixing portion 2108 and the second fixing portion 2114 are fitted to press the first fin body 2156 interposed between the first header body 210 and the first header cover 211 to press-fix them.

A filler 216 may be disposed between the first heat sink fins 215 and the first head cap 211. The filler 216 may be foam to fill the space between the first headgear cap 211 and the first headgear body 210; or a heat conductive material, to improve the heat conduction effect of the first heat sink 215.

When the first headband 21 is assembled, please refer to fig. 26 and 27, first, the protective sheet 214, the power FPC 213 and the first heat sink 215 are sequentially stacked, such that the second insertion hole 2140, the first insertion hole 2135 and the third insertion hole 2158 are sequentially aligned; then, the first and second positioning posts 2109 are placed in the first and second grooves 2105, 2106 of the first headband main body 210, so that the first positioning posts 2109 sequentially pass through the second insertion hole 2140, the first insertion hole 2135 and the third insertion hole 2158; the first soft strip 212 is embedded and covered on the outermost step of the second groove 2106, and can be adhered by glue, so that the first soft strip 212 forms a first perforation with the first main body part 2101 of the first head band main body 210 at the notch 2120, and then the movable part 2137 of the power supply FPC 213 passes through the first perforation, and meanwhile, the power supply FPC neck part 2134 of the power supply FPC 213 and the first heat sink neck part 2154 are arranged inside the recess 2102 a; then, the filler 216 is placed on the first body 2111 of the first headgear cover 211, and then the first headgear cover 211 is snapped onto the first headgear main body 210 such that the first connection member 2107 and the second connection member 2117 are connected, while the first mounting portion 2102 is snapped into the first fitting portion 2112 to form a connecting portion for connection with the corresponding end of the first housing assembly 10; this completes the assembly of the first headband 21.

It is to be understood that the first headgear cover 211 is fastened to the first headgear body 210 so as to form a receiving cavity together with a portion corresponding to the first headgear body 210, and that the first body portion 2101 is fastened to the first headgear cover 211 at the first recess 2105 so as to form a receiving cavity; the protection sheet 214, the power supply FPC 213, the first heat sink 215, and the filler 216 can be accommodated in the accommodation cavity; the second recess 2106 communicates with the receiving cavity.

Second headband 22 of lacing assembly 20

Referring to fig. 30 and 31, a perspective assembled view and an exploded view of the second headband 22 according to embodiments of the present disclosure are disclosed. The second headband 22 is similar to the first headband 21, but differs therefrom in that the second headband 22 is not provided with a power supply FPC and a protective sheet therefor. The second headband 22 may include a second headband body 220, a second headband cover 221, and a second soft strip 222 and a second heat sink 225 that are compressed between the second headband body 220 and the second headband cover 221. The second headband body 220 has a configuration substantially identical to that of the first headband body 210, and specifically, referring to fig. 31, the detailed description thereof will not be repeated, but only the main elements thereof will be listed, and the specific matching relationship and functions thereof will be described with reference to the description of the first headband body 210. The second headband body 220 may include a second body portion 2201 and a second mounting portion 2202. The second main body portion 2201 has a length adjustment hole 2203, a second saw tooth 2204, a first groove 2205 and a second groove 2206, wherein two sides of the first groove 2205 are provided with first connecting members 2207, and a first fixing portion 2208 is arranged at a position, adjacent to the second mounting portion 2202, of the first groove 2205. The second mounting portion 2202 is provided with two first connection holes 2200 thereon, and a recess 2202a is formed between the two first connection holes 2200.

Referring to FIG. 32, an exploded perspective view of the second headband 22 according to the embodiment of the present application is shown from another perspective; the second headgear cover 221 is substantially the same in construction as the first headgear cover 211, and will not be described in detail, and only the main elements thereof will be listed, and specific matching and functions will be described with reference to the description of the first headgear cover 211. The second headgear cover 221 may include a second body 2211 and a second fitting portion 2212. The second body 2211 has a second fixing portion 2214, a second side wall 2216 and a second connecting member 2217. The second fitting portion 2212 is provided with two second connection holes 2210.

The second soft strip 222 is made of a flexible material and is flexible, and may be bent freely, and has a generally elongated shape, and the material of the second soft strip may conform to the second headband body 220, and it may be adhered by gluing or the like to the second headband body 220 in the second groove 2206, so that the outer surface of the second soft strip 222 is flush with the outer surface of the second headband body 220, i.e., the surface adjacent to the head of the user.

Second heat sink 225 is substantially the same in construction as first heat sink 215 and may include a second abutment 2252 extending into first housing assembly 10, a second heat sink neck 2254 captured within the throughbore and connected to second abutment 2252, and a second heat sink body 2256 secured within first and second recesses 2205, 2206; referring to fig. 33, the second attachment 2252 is attached to a side wall of the speaker body 9132 of the second speaker 913.

Second fin neck 2254 has a narrower width than fin portions on both sides thereof, e.g., second fin body 2256, and referring to fig. 24, it can be seen that second fin neck 2254 just snaps over the through hole, preventing second fin 225 from loosening.

When the second heat sink body 2256 is placed in the first and second recesses 2205, 2206, the first fixing portion 2208 cooperates with the second fixing portion 2214 to fix the second heat sink body 2256 placed between the second headband body 220 and the second headband cover 221.

The second headband cover 221 is provided with a filler 226 in an area where the second connection 2217 is provided, and the filler 226 is interposed between the second heat sink 225 and the second headband cover 221. The filler 226 may be foam to fill a space between the second headband cover 221 and the second headband body 220; and may be a heat conductive material to improve the heat conduction effect of the second heat sink 225.

In assembling the second headband 22, referring to fig. 31 to 32, the second heat sink 225 is first placed in the first recess 2205 and the second recess 2206 of the second headband body 220, and then the second soft strip 222 is embedded and covered on the outermost recess of the second recess 2206, and can be adhered by glue; second fin neck 2254 is then placed within recess 2202 a; at this time, the second filler 226 is placed on the second headband cover 221, and then the second headband cover 221 is fastened to the second headband body 220 such that the first connecting member 2207 and the second connecting member 2217 are connected, and at the same time, the second mounting portion 2202 is fastened to the second mounting portion 2212 to form a connecting portion to be connected to the corresponding end of the first shell assembly 10; this completes the assembly of the second headband 22.

It is understood that the second headband cover 221 is fastened to the second headband main body 220, a receiving cavity is formed by the second headband main body 220 and the second main body portion 2201 fastened to the second headband cover 221 at the first groove 2205; the second heat sink 225 and the filler 226 may be accommodated in the accommodating cavity; the second groove 2206 communicates with the receiving cavity.

The assembly of the strap assembly 20 to the first housing assembly 10 is described in detail as follows:

referring to fig. 1, 5, 6, 7 and 24, when the first headband 21 is assembled to the first housing assembly 10, the convex pillar 1123 at one end of the main front shell 11 of the first housing assembly 10 is first inserted through the connecting parts of the first headband 21 in sequence, for example, the convex pillar 1123 is inserted through the first and second connecting holes 2100 and 2110; then, the main front shell 11 and the main rear shell 12 are fastened, and bolts pass through the through holes 1221 to be connected with the bosses 1123, so as to assemble the first head band 21 to the first housing assembly 10. Similarly, the second headband 22 may also be assembled to the first shell assembly 10.

For the positional relationship and the connection relationship of the first heat sink 215, the second heat sink 225, and the power FPC 213 inside the first housing assembly 10, reference may be made to fig. 2, fig. 3, fig. 28, and fig. 33; the wiring portion 2132a of the power FPC 213 is connected to the PCB81 on the main board 80, such as soldering; the wiring portion 2132b of the power FPC 213 is connected to the first microphone 921 in the microphone assembly 92, such as soldering; the first heat sink 215 extends into the first housing assembly 10, and the first attaching portion 2152 thereof is attached to the outer side wall of the speaker body 9112 of the first speaker 911. The second heat sink 225 extends into the first housing assembly 10, and the second attachment 2252 thereof is attached to the outer sidewall of the speaker body 9132 of the second speaker 913.

It should be noted that the connection between the first and second head straps 21 and 22 and the first housing assembly 10 is not limited to the connection between the protruding columns 1123, the connection holes and the through holes 1221, and any type of connection member may be used as long as the strap assembly 20 can be connected to the first housing assembly 10.

The number, structure and position of the heat dissipation fins, the power supply FPC 213, the protective sheet 214 and the padding filled in the first headband 21 and the second headband 22 may be adjusted according to the actual situation, for example, the first headband 21 and the second headband 22 may be adjusted to be filled with the heat dissipation fins, the power supply FPC 213, the protective sheet 214 and the padding; of course, other structures or parts of existing structures may be refilled or deleted according to actual situations, such as filling a spacer between the heat sink and the power supply FPC, for example, both the first headband 21 and the second headband 22 may be adjusted to fill only the heat sink inside, such as one of the first headband 21 and the second headband 22 may be a normal headband having only length adjustment holes; the configuration of the first headband 21 and the second headband 22 may be adapted according to the difference of the inner filling.

It will be appreciated that the first headband 21 and the second headband 22 may also be integral, i.e. used as one headband; for example, one end of the strap assembly may be overlapped with the other end of the strap assembly, and the middle of the strap assembly may be connected to the main housing, and the strap assembly 20 may be adjusted by adjusting the length of the overlapped portion; the first headband 21 and the second headband 22 are used as one headband, and other connection methods may be used, which are not limited herein.

Second housing assembly 30

Referring to fig. 34 and 35, which illustrate an exploded perspective view and an assembled view of the second housing assembly 30 according to an embodiment, the second housing assembly 30 may include a front bottom shell 31, a rear bottom shell 32, and a connecting member 33 connecting the front bottom shell 31 and the rear bottom shell 32. The second housing component 30 can house the strap assembly 20 and the slack adjustment mechanism 40.

Bottom front shell 31 of second housing assembly 30

Referring to fig. 34, the bottom front case 31 may be made of a hard material, and may include a first passage case 311 and a first power supply case 312 formed to extend downward from the first passage case 311.

The first passage housing 311 is integrally formed in a bar-shaped curved shape to match with a head shape of a user and to be worn by the user, and inner and outer surfaces thereof are smooth curved surfaces. First passageway shell 311 is including being the crooked shape body 3110 of bar and the first protruding edge 3111 and the second protruding edge 3112 of setting of buckling to bottom rear shell 32 side from two long limit edges of body 3110, and wherein first protruding edge 3111 is located the top of body 3110, and second protruding edge 3112 is located the below of body 3110.

The body 3110 is provided with third fasteners 3113 at two opposite ends thereof, and the third fasteners 3113 may include a plurality of protrusions 3114 extending outward from the end of the edge of the body 3110 and a plurality of bumps 3115 adjacent to the end edge; wherein, the bump 3115 may be disposed on a surface facing a side of the bottom rear case 32; or may be provided on the surface of the side remote from the bottom rear shell 32.

The first and second rims 3111, 3112 are provided with a first buckle 3116 at two opposite inner sides, and the first buckle 3116 may be a plurality of protrusions uniformly arranged.

The edge of the body 3110 connected to the first flange 3111 is provided with a plurality of grooves 3118, the grooves 3118 are located at the center of the longer edge of the body 3110 and opposite to the first power supply housing 312, and the grooves 3118 are used for avoiding corresponding elements on the bottom rear housing 32.

The first power supply housing 312 includes a first power supply housing 3120 extending downward from a middle portion of a longer side of the body 3110 where the second protruding edge 3112 is located, and a protruding edge 3121 bent from an outer edge of the first power supply housing 3120 toward the bottom rear housing 32 side. That is, the second protruding rim 3112 is not provided at the connection of the first power supply case body 3120 and the body 3110 of the first passage case 311, and the second protruding rim 3112 is cut off at a position intermediate to the long side position of the body 3110. Two ends of the second flange 3112, which are formed by being broken, are connected to the flanges 3121 of the first power supply case 312, respectively.

The first power supply case body 3120 has a rectangular shape, and the first power supply case body 3120 is provided with a compensation structure on a surface facing one side of the bottom rear case 32, the compensation structure includes four bosses 3122 having a gradually-changed thickness, the four bosses 3122 are distributed at positions of the first power supply case body 3120 near four corners, and surfaces of the four bosses 3122 facing the bottom rear case 32 are located on the same plane for supporting the battery 35 (as shown in fig. 29).

The first power housing body 3120 is provided with two pairs of first snap structures 3124 between the two bosses 3122 closest to the body 3110 of the first tunnel housing 311 and the body 3110, the two pairs of first snap structures 3124 include two retaining plates 3124a and two snap plates 3124b, the two retaining plates 3124a are spaced apart, the two snap plates 3124b are located between and offset from the two retaining plates 3124a, and each snap plate 3124b is close to a corresponding retaining plate 3124a, the snap plate 3124b and the adjacent retaining plate 3124a form a pair of first snap structures 3124 for positioning and engaging with corresponding elements in the bottom rear housing 32 to separate the first power housing 312 from the first tunnel housing 311.

The lower ledge 3121 is provided with a second snap 3123 facing the bottom rear housing 32, and the second snap 3123 may be a plurality of tabs, and the tabs may be provided with grooves.

Referring to fig. 35, the first power housing 3120 is provided with a connecting member 3126 at a side facing the first housing assembly 10, in one embodiment, the connecting member 3126 is two convex columns, and a through hole 3127 is formed between the two convex columns.

Bottom rear shell 32 of second housing assembly 30

Referring to fig. 36, the bottom rear case 32 may be made of a hard material, and may include a second channel case 321 corresponding to the first channel case 311 and a second power case 322 corresponding to the first power case 312, and the battery 35 is installed inside the second power case 322. The second power supply case 322 and the battery 35 mounted therein may constitute a power supply module.

Referring to fig. 37, the second passage housing 321 is substantially similar in shape and configuration to the first passage housing 311 so that they are fitted to each other, and has a strip-shaped curved shape as a whole. The second channel 321 includes a strip-shaped curved body 3210, and a first protruding edge 3211 and a second protruding edge 3212 bent from two long sides of the body 3210 to one side of the bottom front shell 31, where the first protruding edge 3211 is located above the body 3210, and the second protruding edge 3212 is located below the body 3210.

The opposite ends of the body 3210 are respectively provided with a third fastener 3213, the structure of the third fastener 3213 is completely the same as that of the third fastener 3113 of the first channel shell 311, and the third fastener 3214 and the bump 3215 are not repeated herein. The third fasteners 3113, 3213 of the first channel shell 311 and the second channel shell 321 are engaged with the corresponding structure of the connecting member 33, so as to fix and combine the two ends of the first channel shell 311 and the second channel shell 321.

The first and second convex edges 3211, 3212 are provided with a first fastening element 3216 at two opposite outer sides, and the first fastening element 3216 may be a plurality of grooves arranged uniformly so as to cooperate with the first fastening element 3116 of the first channel housing 311, i.e. a plurality of protrusions, thereby fastening the first channel housing 311 and the second channel housing 321 together to form a channel for the lace assembly 20 to pass through.

A snap 3217 is disposed on the first convex edge 3211 at a position corresponding to the groove 3118 on the first convex edge 3111 of the bottom front shell 31 toward the bottom front shell 31, so as to be engaged with a related element of the slack adjuster 40, wherein the corresponding groove 3118 on the bottom front shell 31 plays a role in avoiding during the engagement between the snap 3217 and the related element of the slack adjuster 40.

The second power supply housing 322 includes a second power supply housing 3220 recessed outward from the middle of the body 3210 of the second channel housing 321 and extending downward, a side wall 3221 bent and extending from the edge of the second power supply housing 3220 toward the bottom front housing 31, a separating plate 3222 located in the second power supply housing 322, and a power supply support 324 located below the separating plate 3222 and installed in the second power supply housing 322.

The length of the second power supply case body 3220 is the same as the length of the first power supply case body 3120, and the width of the second power supply case body 3220 is approximately the sum of the width of the first power supply case body 3120 and the width of the body 3210 of the second passage case 321.

A through hole boss 3220a is disposed at a central position of the second power source casing body 3220 close to the upper side wall 3221, two symmetrically disposed isolation plates 3225 are disposed at two sides of the through hole boss 3220a, and each isolation plate 3225 is provided with a recess 3226 facing the bottom front casing 31 to cooperate with related elements of the slack adjusting mechanism 40.

A through hole 3220b is further formed on the second power shell body 3220 to install a power key 3220c (see fig. 34 for details).

A second latch 3223 is disposed on the lower side wall 3221 of the second power supply housing 322 at a position close to the edge, and the second latch 3223 is a plurality of protrusions spaced apart from each other and corresponding to the second latch 3123 (e.g., a plurality of tabs) of the first power supply housing 312, so that the second latch 3123 of the first power supply housing 312 and the second latch 3223 of the second power supply housing 322 are engaged with each other.

A fastening structure 3224 is further disposed on the sidewall 3221 below the second power supply housing 322, and the fastening structure 3224 includes two symmetrically disposed protrusions 3224a and a plurality of gradually-varied-width limiting plates 3224b disposed between the two protrusions 3224 a. The protrusions 3224a are farther from the outer edge of the lower sidewall 3221 than each protrusion of the second latching member 3223.

Referring to fig. 38, a heat dissipation hole 3221a is formed on a sidewall 3221 of the second power supply housing 322 adjacent to the second channel housing 321.

With reference to fig. 37, two parallel positioning plates 3221b are disposed on the lower side wall 3221 of the second power supply housing 322 adjacent to the left and right side walls 3221.

The partition 3222 divides the second power housing 322 into two chambers, and the upper chamber is used for accommodating the tightness adjusting mechanism 40 and allowing the lace assembly 20, i.e., the first and second head bands 21 and 22, to pass through. The lower chamber is then used to house a battery 35.

The separation plate 3222 is bent several times to form two bending portions 3227 and a supporting portion 3228 connected to the two bending portions 3227.

The two bending portions 3227 are located at the bearing portion 3228 far away from the central position, and the top of the two bending portions 3227 is higher than the bearing portion 3228, so that a space is formed at the bottom of the bending portion 3227 to accommodate the limiting plate 3124a of the first latching structure 3124 of the bottom front shell 31, and the limiting plate 3124a is in contact with the bottom of the bending portion 3227.

The first buckle 3229 is disposed on the supporting portion 3228 between the two bending portions 3227 and close to the bending portion 3227, the first buckle structure 3229 is two protrusions, and the positions of the two protrusions correspond to the positions of the two buckling plates 3124b of the first buckle structure 3124 of the first power supply housing 312, so that the two protrusions are buckled with each other, thereby buckling the first power supply housing 312 and the separating plate 3222 together.

Two openings 3228a are disposed behind the corresponding positions of the supporting portion 3228 and the first engaging structure 3229, so as to engage with corresponding structures on the power bracket 324.

A bearing rib 3228b is disposed at a central position of the bearing portion 3228, and is installed between the bearing portion 3228 and the second power supply shell body 3220, and is respectively perpendicular to the bearing portion 3228 and the second power supply shell body 3220, so as to increase strength of a joint surface between the bearing portion 3228 and the second power supply shell body 3220; and may even be used to support the slack adjuster assembly 40.

Referring to fig. 37 and 39, the power bracket 324 is mounted in the accommodating cavity under the second power shell 322, and has a bracket body 3240 mounted on the second power shell 3210, and a first mounting plate 3242 and a second mounting plate 3244 extending from two opposite sides of the bracket body 3240.

One surface of the support body 3240 facing the second power supply housing 3210 is provided with reinforcing ribs 3240a arranged in a criss-cross manner, and the height of each reinforcing rib 3240a gradually decreases from the center to both sides, so that after the support body 3240 contacts the arc-shaped second power supply housing 3210, the surface of the support body 3240 facing the bottom front housing 31 is a flat surface to bear a battery gasket 3243 (as shown in fig. 36), the length of the battery gasket 3243 is the same as the distance between the two positioning plates 3221b, and is also the same as the length of the battery 35, and the battery gasket is mounted on the support body 3240, and both ends of the battery gasket extend beyond the support body 3240 to abut against the two positioning plates 322b, so as to stably bear the battery 35.

The first and second mounting plates 3242, 3244 are disposed in parallel, the first mounting plate 3242 is configured to be mounted on the partition plate 3222, and the second mounting plate 3244 is configured to be mounted on the lower side wall 3221.

The first mounting plate 3242 is provided at an edge position with a fastening portion 3245 corresponding to the opening 3228a provided in the partition plate 3222, and the fastening portion 3245 is fastened to the opening 3228a, so that the first mounting plate 3242 is mounted on the partition plate 3222.

The second mounting plate 3244 has an engaging structure 3246 on a surface facing the lower sidewall 3221 for engaging with the engaging structure 3224 on the lower sidewall 3221. The engaging structure 3246 includes a protrusion 3247 matching with the protrusion 3224a of the engaging structure 3224 and a position-limiting plate 3248 matching with the position-limiting plate 3224b of the engaging structure 3224.

Connecting piece 33 of second housing component 30

Referring to fig. 34 and 40, the connecting element 33 may include a connecting element main body 331 and a sidewall 332 extending from an edge of the connecting element main body 331.

As shown in fig. 34 and 40, the connector main body 331 is substantially rectangular, and corners thereof are rounded; and it and the four side walls 332 enclose an accommodating cavity 333. The connector body 331 has a through hole 3310 for the lace assembly 20 to pass through. The connecting member main body 331 is provided with a fastening member 3313 in the accommodating cavity 333, and the fastening member 3313 is fastened to the third fastening member 3113 of the first passage casing 311 and the third fastening member 3213 of the second passage casing 321, respectively. Specifically, the fastening component 3313 includes a locking slot 3315 corresponding to the protrusion 3114 of the third fastening component 3113, a locking slot 3315 corresponding to the protrusion 3214 of the third fastening component 3213, a locking piece 3314 corresponding to the protrusion 3115 of the third fastening component 3113, and a locking piece 3314 corresponding to the protrusion 3215 of the third fastening component 3213.

After the front and rear bottom cases 31 and 32 are fastened, the body 3110 of the first passage case 311 and the body 3210 of the second passage case 321 form a passage into which the lace assembly 20 extends; after the first power supply housing 312 and the second power supply housing 322 are engaged, a space above the partition plate 3222 may be defined as a first receiving cavity, and a space below the partition plate 3222 may be defined as a second receiving cavity; the first containing cavity is communicated with the channel, and the first containing cavity and the channel can be defined as a first channel together; the first receiving cavity can receive the tightness adjusting mechanism 40 in addition to the first headband 21 and the second headband 22 which can be overlapped with each other, so as to adjust the length of the overlapped part of the first headband 21 and the second headband 22, and therefore, the solid parts forming the channel and the first receiving cavity can also be defined as the headband and the tightness adjusting mechanism shell (also can be defined as the first shell); the second housing cavity is used for housing a power source, such as a battery 35, and can be defined as a power source housing (also defined as a second housing).

It is understood that, after the front bottom case 31 and the rear bottom case 32 are fastened, the first power supply case 312, the second power supply case 322 and the body 3110 of the first passage case 311 may be defined as a first case; and the first passage case 311 and the second passage case 321 positioned at both sides of the first case may be defined as a second case.

The above various names, for example: the passageway, accept the chamber, first accept the chamber, the chamber is accepted to the second, first casing, the second casing, bandeau and elasticity adjustment mechanism casing, power supply housing can adjust according to actual conditions, this application is not limited to the restriction to above-mentioned name, can exchange according to actual conditions name of class structure, for example, the passageway also can be called first and accept the chamber, and originally first accepting the chamber this moment can be called the second and accept the chamber, and originally second accepts the chamber and can be called the third and accept the chamber, and the name of first casing and second casing also can be exchanged.

Slack adjuster mechanism 40

Referring to FIG. 41, an exploded perspective view of the slack adjustment mechanism 40 of an embodiment of the present application is disclosed. The slack adjustment mechanism 40 can include a first housing 41, a second housing that cooperates with the first housing 41 (where the second housing is the bottom rear shell 32 of the second housing assembly 30 described above, the bottom rear shell 32 can be a common element of the slack adjustment mechanism 40 and the second housing assembly 30), and a ratchet-pawl mechanism 42. The first housing 41 and the second housing are snap-fitted to form a box body in which a main body portion of the ratchet-pawl mechanism 42 can be housed. The two head straps (i.e. the first head strap 21 and the second head strap 22) of the strap assembly 20 can be extended into the box body and connected to the ratchet-pawl mechanism 42 in an overlapping manner, and the length of the overlapping of the first and second head straps 21 and 22 is adjusted by the ratchet-pawl mechanism 42; here, the second housing is not an essential component, and the slack adjuster mechanism 40 may be formed by only the ratchet-pawl mechanism 42 being attached to the first housing 41.

First housing 41 of slack adjustment mechanism 40

Referring to fig. 42, a perspective view of the first housing 41 at different angles is disclosed. The first housing 41 may include a housing bottom plate 410. The case bottom plate 410 may be a rectangular plate having a uniform thickness, and a center hole 4100 is formed at the center thereof.

The two opposite long sides of the bottom plate 410 of the housing are formed with side plates 412 facing the second housing (i.e., the bottom rear case 32), and the height of each side plate 412 is gradually reduced from the middle to both sides so that the surfaces of the side plates 412 facing the second housing are arc-shaped to be in close contact with the second housing. Two ends of one of the side plates 412 are provided with first mounting portions 413 facing the second housing and having a column shape, and the first mounting portions 413 can be provided with internal threads so as to fix the first housing 41 to the bottom rear case 32 by bolts passing through the first mounting portions 413. A first engaging structure 4120 is formed in the middle of the side plate 412 provided with the first mounting portion 413, and in one embodiment, the first engaging structure 4120 is a groove and a bump formed above the groove, so that when the first housing 41 is fixed with the bottom rear shell 32, the bump is placed on the bearing rib 3228b to support the first housing 41. The other side plate 412 without the first mounting portion 413 is formed with a second engaging structure 4122, and in an embodiment, the second engaging structure 4122 is composed of three grooves arranged at intervals and a protrusion formed above a middle groove so as to be clamped with the hook 3217 on the bottom rear shell 32 through the grooves, thereby completing the fixing of the first shell 41 and the bottom rear shell 32.

The case bottom plate 410 is provided with a ratchet 414 having a circular ring shape, a reinforcing rib 415 disposed around the ratchet 414, and second mounting portions 416 distributed on the outer circumference of the ratchet 414, on a surface facing the second case (i.e., the bottom rear case 32).

Inner teeth 4140 are arranged on the inner wall of the ratchet wheel 414, the central hole 4100 and the ratchet wheel 414 are coaxially arranged, the bottom of the ratchet wheel 414 can be recessed towards the direction far away from the second shell and is provided with convex ribs 4142, and the convex ribs 4142 comprise a plurality of circular first convex ribs 4143 which are concentrically arranged with the central hole 4100 and strip-shaped second convex ribs 4144 which are arranged in a crossed manner with the first convex ribs 4143 and are divergently arranged towards the periphery by taking the center of the central hole 4100 as the center.

The ribs 415 can include a plurality of parallel first ribs 4150 extending from the outer peripheral wall of the ratchet wheel 414 and a plurality of parallel second ribs 4152 disposed across the first ribs 4150. The first ribs 4150 extend from the outer peripheral wall of the ratchet 414 to the edges of the two relatively short sides of the housing bottom plate 410. The height of the first rib 4150 is gradually reduced from the outer peripheral wall of the ratchet 414 toward the shorter edge of the bottom plate 410 of the case so that the first rib 4150 is integrally arc-shaped toward the top surface of the second case to be engaged with the bottom rear case 32, so that the first and second head straps 21, 22 extending into the box body are attached to the first rib 4150, and thus the first and second head straps 21, 22 will not be bent at a corner. The second ribs 4152 are arranged perpendicular to the first ribs 4150, i.e., along the direction perpendicular to the both long sides of the housing bottom plate 410.

Ratchet-pawl mechanism 42 of slack adjuster mechanism 40

Referring to fig. 41, the ratchet-pawl mechanism 42 may include a ratchet wheel 414 formed on the first housing 41, a pawl assembly 420 engaged with the ratchet wheel 414 and received therein, and a knob assembly 430 mounted on the pawl assembly 420 and driving the pawl assembly 420 to rotate and slidably connected to the central bore 4100.

Referring to fig. 43, the pawl assembly 420 includes a first plate 421, a second plate 422 fixedly connected to the first plate 421, a rotating plate 423 disposed between the first plate 421 and the second plate 422, a first pawl 424, a second pawl 425, a first spring 426 and a second spring 427 mounted on the second plate 422, and a gear 428 fixedly mounted on a side of the second plate 422 away from the first plate 421.

The first plate 421 may be a circular plate-shaped structure, and has a central hole 4210, and the central hole 4210 is aligned with the central hole 4100 of the ratchet 414 and has the same central axis. The first board 421 has a first connecting portion 4212 and a second connecting portion 4214 on a surface facing the second board 422, wherein the second connecting portion 4214 is prism-shaped, the first connecting portion 4212 is cylindrical, and peripheral walls of the first and second connecting portions 4212 and 4214 are respectively provided with a protruding strip so as to be fastened and matched with a corresponding structure on the second board 422 to fixedly connect the first board 421 and the second board 422.

Referring to fig. 44, the second shield 422 has the same shape and size as the first shield 421, and a central hole 4220 is formed in the middle of the second shield, and the central hole 4220 is aligned with the central hole 4210 of the first shield 421. The second shutter 422 is provided with a first click portion 4222 and a second click portion 4224 on a surface facing the first shutter 421. The second latch portion 4224 has the same shape as the second coupling portion 4214 of the first flap 421, but has a different size, so that the second coupling portion 4214 of the first flap 421 is inserted into the second latch portion 4224, and the second latch portion 4224 includes a first latch wall 4220a and a second latch wall 4220b arranged at an angle to the first latch wall 4220a, that is, the distance between the first latch wall 4220a and the second latch wall 4220b gradually increases along the outward direction of the central hole 4220. The first catching portion 4222 has the same shape as the first coupling portion 4212 of the first flap 421, but has a different size so that the first coupling portion 4212 of the first flap 421 is inserted into the first catching portion 4222. The second shutter 422 is further provided at a surface facing the first shutter 421 with a first mounting shaft 4225 for mounting the first pawl 424, a second mounting shaft 4226 for mounting the second pawl 425, a first mounting frame 4227 for mounting the first spring 426, and a second mounting frame 4228 for mounting the second spring 427.

The first baffle 421 and the second baffle 422 can also be used as a mounting member, the second clamping portion 4224 and the second connecting portion 4214 can be used as limiting portions to be matched with the rotating plate 423, and can also be used as fixing portions to fix the first baffle 421 and the second baffle 422 together; the first snap joint 4222 and the first coupling portion 4212 serve as fixing portions to fix the first and second shutters 421 and 422 together.

The mounting member is not limited to the assembly of the first stop 421 and the second stop 422, and the first pawl 424 and the second pawl 425 may be engaged with the ratchet 414 in a contact manner; that is, the mounting member is provided with a notch or notch-like structure to allow the first pawl 424 and the second pawl 425 to extend out of the space defined by the mounting member to engage the ratchet wheel 414; the mounting member may also be a box with a gap or similar;

of course, the mounting member may be only the first flap 421 or the second flap 422, for example, the mounting member is the second flap 422, and the second clamping portion 4224 and the second connecting portion 4214 are formed on the first flap 421 or the second flap 422 as the limiting portion.

The first mounting shaft 4225 and the second mounting shaft 4226 are respectively located at two sides of the first clamping portion 4222 and are symmetrically arranged relative to the first clamping portion 4222.

The first mounting frame 4227 and the second mounting frame 4228 are symmetrically arranged relative to the first clamping portion 4222, and the shapes, sizes and structures of the first mounting frame and the second mounting frame are completely the same.

Referring to fig. 44 and 45, the first mounting frame 4227 includes a first blocking wall 4227a, a second blocking wall 4227b arranged at an angle with respect to the first blocking wall 4227a, and a connecting wall 4227c connecting one end of the first blocking wall 4227a and one end of the second blocking wall 4227 b. The first blocking wall 4227a, the second blocking wall 4227b and the connecting wall 4227c enclose an accommodating space 4227d for accommodating the first spring 426. The first blocking wall 4227a extends from the outer peripheral wall of the first engaging portion 4222, a locking shaft 4227e is disposed on the connecting wall 4227c facing the accommodating space 4227d, and the first spring 426 is sleeved on the locking shaft 4227 e.

Since the second mounting frame 4228 has the same structure as the first mounting frame 4227, detailed description thereof is omitted and only elements thereof are listed. The second attachment frame 4228 includes a first blocking wall 4228a, a second blocking wall 4228b, a connecting wall 4228c, a housing space 4228d, and a latch 4228e. The first blocking wall 4227a of the first mounting frame 4227 is coupled to the first blocking wall 4228a of the second mounting frame 4228, and one end of the coupling wall 4227c and one end of the coupling wall 4228c are also coupled to each other.

It should be noted that the first spring 426 and the second spring 427 may also be other elastic members, such as a tension spring, a compression spring, an object providing a stretching force, etc., so that the first pawl 424 and the second pawl 425 cooperate with the ratchet 414 to complete the switching between the engaged state and the disengaged state; the first mounting frame 4227 and the second mounting frame 4228 may be changed to have other structures capable of fixing the elastic members according to the elastic members.

The rotating plate 423 is an eccentric wheel structure having a through hole 4230, but the rotating plate 423 may be integrated with the knob assembly 430 at the through hole 4230; the through hole 4230 is aligned with and has the same axis as the central hole 4220 of the second shutter 422. In one embodiment, the inner surface of the through hole 4230 is polygonal, such as hexagonal. The end of the rotating plate 423 away from the through hole 4230 is provided with a notch 4232, and the shape of the notch 4232 is the same as the shape of the first clamping portion 4222 of the second baffle 422, but the size of the notch 4232 is different from the size of the first clamping portion 4222, so that the first clamping portion 4222 is accommodated in the notch. Here, the second snap portions 4224 and the second connecting portions 4214 serve as stopper portions to be engaged with the notches 4232; the gap 4232 has two opposite inner walls, namely a first inner wall 4232a and a second inner wall 4232b arranged opposite to the first inner wall 4232 a; the peripheral surface of the rotating plate 423 includes an outer wall surface 4234. When the rotating plate 423 rotates around the axis of the through hole 4230, the rotating plate 423 and the second engagement portion 4224 have only three states: a state where only the first inner wall 4232a is in contact with the first chuck wall 4220a, a state where the rotation plate 423 is not in contact with the second chuck portion 4224, and a state where only the second inner wall 4232b is in contact with the second chuck wall 4220 b; that is, the stopper portion is disposed in both a contact state and a non-contact state with the inner wall surface of the notch 4232 so that the rotation plate 423 rotates at a certain angle around its rotation axis (the axial center of the through hole 4230).

Referring to fig. 44 to 46, the first pawl 424 is pivotally mounted on the first mounting shaft 4225 of the second stop 422 and can rotate around the first mounting shaft 4225. A pivot hole 4240 is formed at a middle position of the first pawl 424 for pivotally connecting to the first mounting shaft 4225. The first pawl 424 has two opposing ends, namely: a first end 4242 connected to the first spring 426 and a second end 4244 abutting an outer wall 4234 of the swivel plate 423. An installation shaft 4242a is disposed at a side of the first end 4242 facing the accommodating space 4227d of the first installation frame 4227 for installing the first spring 426 thereon, and a side of the first end 4242 facing away from the first installation frame 4227 has an angular edge 4242b, and the angular edge 4242b is used for engaging with the inner teeth 4140 of the ratchet 414 (see fig. 47). The side of the second end 4244 facing the rotating plate 423 is provided with a contact surface 4244a, and in one embodiment, the contact surface 4244a is a cambered surface to linearly contact with the outer wall surface 4234 of the rotating plate 423 to reduce the pressure therebetween.

The second pawl 425 and the first pawl 424 are symmetrically disposed relative to the first latch portion 4222 of the second baffle 422, and both have identical shape and structure, which are not described herein again, and only the elements thereof are listed. The second pawl 425 has a pivot hole 4250, a first end 4252, a second end 4254, a mounting shaft 4252a, an edge 4252b and a contact surface 4254a.

When the first spring 426 is installed, one end of the first spring 426 is sleeved on the latch shaft 4227e in the first installation frame 4227, and the other end of the first spring 426 is sleeved on the installation shaft 4242a of the first pawl 424, so that the first spring 426 is installed in the first installation frame 4227, the first pawl 424 can rotate around the first installation shaft 4225, and when the first pawl 424 rotates, the first pawl 424 drives the first end 4242 of the first pawl 424 to move, thereby pushing the first spring 426 to compress in the first installation frame 4227 to different degrees.

The second spring 427, which has the same structure and function as the first spring 426, is installed in the second installation frame 4228, and thus will not be described in detail.

An outer wall surface 4234 of the rotating plate 423 is a curved surface, and the outer wall surface 4234 is configured to: when the rotating plate 423 rotates around the rotating shaft thereof, the outer wall surface 4234 pushes the first and second pawls 424 and 425 to rotate, respectively, so that the first and second pawls 424 and 425 complete the two states of engagement and disengagement with the ratchet 414. Referring to fig. 45, when no external force is applied to force the rotation plate 423 or the mounting member (combination of the first and second shutters 421 and 422) to rotate; due to the action of the first spring 426 and the second spring 427, when the rotating plate 423 is in a non-contact state with the outer surface of the limiting portion (i.e., the outer surface of the second clamping portion 4224), and the pawl assembly 420 is in a clamping state with the ratchet wheel 414; when the rotating plate 423 is forced to rotate around the axis of the through hole 4230 by the intervention of an external force, two states occur:

(1) When the non-contact state is changed into a state that only the first inner wall 4232a is in contact with the first blocking wall 4220a, in the direction that the rotating plate 423 rotates around the through hole 4230, the distance from the contact position of the first pawl 424 and the outer wall surface 4234 to the through hole 4230 is gradually increased, so that the first end 4242 of the first pawl 424 moves and is disengaged from the inner teeth 4140 of the inner wall of the ratchet wheel 414; while the distance from the contact position of the second pawl 425 with the outer wall surface 4234 to the through hole 4230 gradually decreases, the ratchet wheel 414 presses the second spring 427 of the second pawl 425, so that the second pawl 425 and the inner teeth 4140 of the inner wall of the ratchet wheel 414 are also in a disengaged state; eventually, the pawl assembly 420 disengages from the ratchet wheel 414.

(2) When the non-contact state is changed into a state that only the second inner wall 4232b is in contact with the second chuck wall 4220b, in the direction that the rotating plate 423 rotates around the through hole 4230, the distance from the contact position of the second pawl 425 and the outer wall surface 4234 to the through hole 4230 is gradually increased, so that the second end 4254 of the second pawl 425 moves and is disengaged from the inner teeth 4140 of the inner wall of the ratchet wheel 414; the distance from the contact position of the first pawl 424 and the outer wall surface 4234 to the through hole 4230 gradually decreases, but the ratchet wheel 414 presses the first spring 426 of the first pawl 424, so that the first pawl 424 and the inner teeth 4140 of the inner wall of the ratchet wheel 414 are also in a disengagement locking state; eventually, the pawl assembly 420 disengages from the ratchet wheel 414.

Referring to fig. 43, the gear 428 has a central aperture 4280, and the central aperture 4280 is aligned with and has the same central axis as the central aperture 4220 of the second stop 422. The gear 428 is fixedly disposed on a side of the second shield 422 away from the first shield 421.

Referring also to fig. 48, when the strap assembly 20 is coupled to the slack adjustment mechanism 40, the end of the first strap 21 having the length adjustment aperture 2103 is stacked with the end of the second strap 22 having the length adjustment aperture 2203, such that the first teeth 2104 and the second teeth 2204 are disposed on opposite sides of the two stacked length adjustment apertures 2103, 2203, respectively, and the gear 428 is disposed in the two stacked length adjustment apertures 2103, 2203 and is engaged with the first teeth 2104 and the second teeth 2204.

Referring to fig. 49 and 50, the knob assembly 430 may include a rotating plate 431, a first transmission shaft 432 extending from an inner surface of the rotating plate 431, and a second transmission shaft 433 mounted on the first transmission shaft 432.

The side surface of the rotary plate 431 may have a rough structure, and in one embodiment, the rotary plate 431 has a plurality of grooves arranged in parallel on the outer surface thereof to form a rib between two adjacent grooves.

The first transmission shaft 432 and the second baffle 422 have the same central axis, and the first rotation shaft 432 is sequentially formed with a first connection shaft 4321, a second connection shaft 4322 and a third connection shaft 4323, which are coaxially disposed, in a direction toward the central axis of the second baffle 422. The first connection shaft 4321 and the second connection shaft 4322 are both circular shafts, i.e., the outer peripheral surface is circular and the outer diameter of the first connection shaft 4321 is larger than that of the second connection shaft 4322. The outer circumferential surface of the third connection shaft 4323 is polygonal, in one embodiment, hexagonal, the distance from the center of the hexagon to any one side of the hexagon is smaller than the radius of the second connection shaft 4322, and a center hole 4324 is formed at the center of the third connection shaft 4323, and the center hole 4324 has an internal thread.

The second transmission shaft 433 has the same central axis as the first transmission shaft 432, and a disc 4330, a first connection shaft 4331 connected to the disc 4330, a second connection shaft 4332 connected to the first connection shaft 4331, and a third connection shaft 4333 connected to the second connection shaft 4332, which are coaxially arranged, are sequentially formed in an axial direction away from the rotating disk 431.

The outer diameter of the disc 4330 is larger than that of the first connecting shaft 4331 and larger than that of the gear 428, a recess 4330a is formed at the bottom thereof, and a through hole 4330b is formed at the middle position of the recess 4330 a. The inner wall of the recess 4330a has a polygonal shape, which is hexagonal in one embodiment, to be engaged with the third connecting shaft 4323 of the first transmission shaft 432; when the gear 428 is disposed in the two length-adjusting holes 2103, 2203 of the first and second head straps 21, 22, the disc 4330 cooperates with the gear 428 and the second baffle 422 to limit the position of the first and second head straps 21, 22 and prevent the first and second head straps 21, 22 from being disengaged from the gear 428.

The first connecting shaft 4331 and the third connecting shaft 4333 are circular shafts, i.e., the outer peripheral surface is circular and the outer diameter of the first connecting shaft 4331 is larger than that of the third connecting shaft 4333. The outer circumferential surface of the second connection shaft 4332 is polygonal, and in one embodiment, hexagonal, and the distance from the center to any one side of the hexagon is smaller than the radius of the first connection shaft 4331 and larger than the radius of the third connection shaft 4333. The second connection shaft 4332 has a shape and size matched with those of the through hole 4230 of the rotation plate 423, thereby fixedly connecting the rotation plate 423 to the second connection shaft 4332.

When the tying band assembly 20, the second housing assembly 30 and the tightness adjusting mechanism 40 are assembled, the tying band assembly 20 is assembled, the first headband 21 and the second headband 22 of the tying band assembly 20 respectively pass through the through hole 3310 of one connecting piece 33, the first transmission shaft 432 of the rotating disc 431 passes through the through hole boss 3220a from the rear side of the bottom rear shell 32, and then the disc 4330 is installed on the third connecting shaft 4323; thereby engaging the second transmission shaft 433 with the first transmission shaft 432, and then screwing the screw 434 through the through hole 4330b of the bottom of the disc 4330 and the center hole 4324 of the third connection shaft 4323 of the first transmission shaft 432, thereby firmly connecting the second transmission shaft 433 with the first transmission shaft 432.

Overlapping the position of the length adjusting hole 2103 of the first headband 21 with the position of the length adjusting hole 2203 of the second headband 22, then placing the gear 428 in the length adjusting hole 2103 and the length adjusting hole 2203, passing the second transmission shaft 433 through the gear 428 and the central hole 4210, the central hole 4220 of the second baffle 422, installing the first pawl 424, the second pawl 425, the first spring 426, the second spring 427 and the rotating plate 423 on the second baffle 422, for example, passing the rotating plate 423 through the third connecting shaft 4333 of the second transmission shaft 433 and then sleeving the rotating plate 423 on the second connecting shaft 4332 to fix the rotating plate 423 relative to the first and second rotating shafts 432, 433, and simultaneously positioning the second clamping part 4224 on the second baffle 422 in the gap 4232 of the rotating plate 423; the second ends 4242, 4252 of the first pawl 424 and the second pawl 425 contact an outer wall surface 4234 of the rotation plate 423.

Then, the first baffle 421 is fastened to the second baffle 422, and the first connection portion 4212 on the first baffle 421 is fastened to the first fastening portion 4222 on the second baffle 422, so that the first baffle 421 is assembled on the second transmission shaft 433, and the first baffle 421 is fixed relative to the second baffle 422, that is, the first baffle 421 and the second baffle 422 can rotate together in the radial direction relative to the second transmission shaft 433; fixing the first pawls 424, the second pawls 425, the first springs 426, the second springs 427, and the rotating plate 423 between the first shutter 421 and the second shutter 422; the pawl assembly 420 is received in the ratchet wheel 414, and the third connecting shaft 4333 of the second transmission shaft 433 extends into the central hole 4100 in the ratchet wheel 414 to match with each other; then, the first shell 41 is buckled with the bottom rear shell 32; at this time, the bottom of the gear 428 abuts against the disc 4330, and the disc 4330 presses and limits the first headband 21 and the second headband 22 (see fig. 51); the protrusions of the first engaging structure 4120 are disposed on the supporting ribs 3228b to support the first housing 41; the second fastening structure 4122 is fastened to the hook 3217 on the rear bottom housing 32, and the first mounting portion 413 is fixed to the rear bottom housing 32 by screws; the first and second head straps 21, 22 are thereby secured within the slack adjustment mechanism 40, and the assembly of the strap assembly 20 with the slack adjustment mechanism 40 is completed.

The buckling part 3245 on the power supply bracket 324 is buckled on the corresponding opening 3228a on the bearing part 3228; the buckling structure 3246 on the power bracket 324 is buckled on the corresponding buckling structure 3224 on the side wall 3221; next, a battery gasket 3243 is laid on the power supply bracket 324, and the battery 35 is placed; assembling the bottom front shell 31 and the bottom rear shell 32; a first buckle 3216 on the bottom rear shell 32 is buckled with a corresponding first buckle 3116 on the first channel shell 311; the second buckling piece 3223 on the bottom rear shell 32 is buckled with the corresponding second buckling piece 3123 on the convex edge 3121; then, the two connecting members 33 are installed, and the fasteners 3313 of the connecting members 33 are fastened to the third fasteners 3113 of the front bottom shell 31 and the third fasteners 3213 of the rear bottom shell 32, so as to fix the front bottom shell 31 and the rear bottom shell 32, thereby completing the assembly of the belt assembly 20, the second housing assembly 30 and the slack adjuster 40.

When the strap assembly 20 is adjusted, referring to fig. 45, in the initial state, the first spring 426 pushes up the first pawl 424 such that the first end 4242 engages with the inner teeth 4140 of the ratchet wheel 414, and the second spring 427 pushes up the second pawl 425 such that the first end 4252 engages with the inner teeth 4140 of the ratchet wheel 414; at this time, the first pawl 424 and the second pawl 425 contact the rotating plate 423, so that the rotating plate 423 and the second clamping portion 4224 are in a non-contact state; the strap assembly 20 acts on the mounting member such that when the mounting member is rotated in either direction, a pawl engages the inner teeth 4140 of the ratchet wheel 414; so that the limit part of the mounting member cannot be in direct contact with the rotating plate 423; the first baffle 421 is forced to be unable to complete rotation, so as to clamp the headgear assembly 20, and to avoid loosening of the strap assembly 20;

when the length of the lace assembly 20 is adjusted by using the knob assembly 430, the knob assembly 430 drives the rotating plate 423 to rotate, so that the non-contact state between the rotating plate 423 and the second clamping portion 4224 is changed into a state where only the first inner wall 4232a is in contact with the first clamping wall 4220a or a state where only the second inner wall 4232b is in contact with the second clamping wall 4220b, and both of the states result in the pawl assembly 420 and the ratchet wheel 414 being disengaged from each other, and further drives the first baffle 421 to rotate, and the tightness of the lace assembly 20 is adjusted by using the gear 428.

It is understood that the first housing 41 can also be the bottom front shell 31 of the second housing assembly 30, and the ratchet wheel 414 can be formed on the body 3110, and the central hole 4100 can also be formed on the body 3110, and the ratchet-pawl mechanism 42 cooperates with the ratchet wheel 414; in addition, when the first and second head bands 21, 22 are overlapped and connected to the tightness adjusting mechanism 40, and the tightness adjusting mechanism 40 adjusts the overlapping length of the first and second head bands 21, 22, the distances from the first and second head band covers 211, 221 to the tightness adjusting mechanism 40 and to the head bands and the tightness adjusting mechanism housing are also adjusted; the front bottom shell 31 and the rear bottom shell 32 may form a slack adjuster housing as a part of the slack adjuster, but the first housing 41 and the rear bottom shell 32 may form a slack adjuster housing.

Force receiving assembly 50

Referring to fig. 1, a perspective view of a head-mounted device 100 according to an embodiment is disclosed, in which a force-receiving member 50 includes a first force-receiving member 51 disposed on a first housing assembly 10 and a second force-receiving member 52 disposed on a second housing assembly 30. In this embodiment, the first housing member 10, the strap member 20, the second housing member 30 and the slack adjuster mechanism 40 may form a looped frame with adjustable slack, and the first force receiving member 51 and the second force receiving member 52 may be located on one side and the other side of the looped frame, for example, on the upper and lower sides of the first housing member 10 and the second housing member 30, respectively. The first force receiving member 51 is inclined to a side close to the second force receiving member 52; in addition, the first force-bearing member 51 is a first force-bearing point, the first housing component 10 is a second force-bearing point, the second force-bearing member 52 is a third force-bearing point, and the head-mounted device 100 is stably supported and worn through the first, second and third force-bearing points.

First force-receiving member 51 of force-receiving assembly 50

Referring to fig. 2 and 52, perspective views of the first force-bearing member 51 from two different viewing angles are disclosed. The first force-receiving member 51 may include a supporting plate 511, a mounting plate 512 disposed at an angle to the supporting plate 511, a neck 513 between and connecting the supporting plate 511 and the mounting plate 512, and a cushion 514 disposed on the supporting plate 511.

The supporting plate 511 may be a quadrangular plate body, and a surface thereof away from the second housing member 30 and the cushion 514 may be curved. The side of the support panel 511 to which the cushion 514 is attached may be concavely curved to approximately match the contour of the forehead or the upper portion of the forehead of the user. The support plate 511 is extended from one side of the mounting plate 512 and inclined toward one side of the mounting pad 514 such that the mounting plate 512 is disposed at an obtuse angle to the support plate 511. The neck 513 may have the same extension direction as the support plate 511, i.e., extend from one side of the mounting plate 512, such that the neck 513 is disposed at an obtuse angle to the mounting plate 512; the neck 513 may also be bent upward from the mounting plate 512 such that the neck 513 is disposed at a right angle or an acute angle to the mounting plate 512.

The mounting plate 512 is a plate-shaped structure having a thickness, is made of a rigid material, and is used to be mounted in cooperation with the top plate 111 of the main front case 10 and the main case garnish 15, for example, is interposed between the top plate 111 and the main case garnish 15. The mounting plate 512 is provided with a strip-shaped adjustable through hole 5121 corresponding to the convex column 156 on the lower surface 155 of the main casing decorating part 15 for the convex column 156 to pass through. The adjustable through holes 5121 may be two and may be parallel to each other. The neck part 513 is made of a hard material, and the thickness of the neck part 513 in the front-rear direction is substantially equal to the depth of the groove 154 of the main decorative trim piece 15; so that the recess 154 of the ornamental body 15 may receive a portion of the neck 513 and may even be able to snugly capture the neck 513.

The soft pad 514 corresponds to the shape of the supporting plate 511 and is fixed to a side of the supporting plate 511 facing the second housing member 30. The cushion 514 and the mounting plate 512 are on opposite sides of the support plate 511, respectively, such that the cushion 514 and the adjustable through-holes 5121 are also on opposite sides of the support plate 511, respectively.

When the first force-receiving member 51 is mounted to the first housing assembly 10, the mounting plate 512 is first placed on the top plate 111 of the main front housing 10, and then the protrusion 156 of the main housing decorative member 15 is inserted into the adjustable through hole 5121 of the mounting plate 512 and the through hole 1114 of the top plate 111 in sequence, and the groove 154 of the main housing decorative member 15 can receive the neck 513 to clamp the neck 513, so that the first force-receiving member 51 is mounted to the first housing assembly 10. Because the mounting plate 512 is provided with the adjustable through hole 5121, the front-back position of the first force-receiving member 51 relative to the main front shell 11 can be adjusted within a certain range, and the adjustable mounting of the front first force-receiving member 51 is realized.

Specifically, the adjustable through hole 5121 in the shape of a bar on the mounting plate 512 of the first force-bearing member 51 and the main housing decoration 15 with the convex pillar 156 placed in the adjustable through hole 5121 constitute the adjustable structure of the present application. The protruding column 156 is inserted into the adjustable through hole 5121 and can be positioned at different positions of the adjustable through hole 5121, so that the adjustable structure can make the front and back position of the first force-receiving member 51 relative to the first housing assembly 10 (e.g. the horizontal position along the direction of the adjustable through hole 5121) adjustable within a certain range. Alternatively, the positions of the adjustable through hole 5121 and the boss 156 may be changed with each other, that is, the adjustable through hole 5121 is disposed on the main housing decoration 15, and the boss 156 is disposed on the first force receiving member 51. Of course, the adjustable structure of the present application is not limited to the form of the adjustable through hole 5121 and the protruding pillar 156, and any structure that can allow the position of the first force-receiving member 51 relative to the first housing assembly 10 to be adjusted can be used.

Force receiving assembly 50 second force receiving member 52

Referring to FIG. 53, an exploded view of the second force-bearing member 52 of the force-bearing assembly 50 and the bottom front shell 31 of the second housing assembly 30 is shown in one embodiment; the second force-bearing member 52 is fixedly mounted on the bottom front shell 31 of the second shell assembly 30; referring to fig. 54, which discloses an exploded perspective view and an assembled perspective view of the second force-receiving member 52 according to an embodiment, the second force-receiving member 52 may include a fixing plate 521 and a soft pad 522 wrapped on the fixing plate 521.

The fixing plate 521 has a shape matched with the shape and size of the first power source housing body 3120 of the bottom front case 31 of the second housing assembly 30, and is provided thereon with a mounting hole 5210 corresponding to the coupling member 3126 of the first power source body 3120.

When the second force-receiving member 52 is mounted to the second housing assembly 30, the soft pad 522 is firstly fitted over the fixing plate 521, and then the fixing plate 521 is aligned with the connection member 3126 of the first power source body 3120, so that the connection member 3126 is tightly inserted into the mounting hole 5210, thereby stably mounting the second force-receiving member 52 to the second housing assembly 30; alternatively, the positions of the connection member 3126 and the mounting hole 5210 may be changed from each other, that is, the mounting hole 5210 is provided on the second housing assembly 30 and the connection member 3126 is provided on the second force-receiving member 52. Of course, the present application is not limited to the form of the mounting hole 5210 and the connecting member 3126, and any means for allowing the second force receiving member 52 to be mounted on the second housing assembly 30 may be used, such as adhesive bonding.

When the user wears the head-mounted device 100, since the strap assembly 20 connects the first shell assembly 10 and the second shell assembly 30 together and forms a wearable annular frame, and the second force-receiving member 52 and the first shell assembly 10 are main force-receiving points, the first shell assembly 10 contacts with the forehead of the user, the second force-receiving member 52 contacts with the back of the head of the user, and the user supports the head-mounted device 100 through the forehead and the back of the head; since the first force receiving members 51 are obliquely disposed toward the second force receiving members 52 in the forehead direction and make contact with a portion above the forehead of the user, the head-mounted device 100 can be stably supported, thereby making the user more comfortable to wear.

While the foregoing is directed to the preferred embodiment of the present application, it will be appreciated by those skilled in the art that various changes and modifications may be made therein without departing from the principles of the application, and it is intended that such changes and modifications be covered by the appended claims.

Claims (19)

1. A protective case for housing a host of head-mounted devices, the protective case comprising:

a first housing comprising:

a top plate; and

the first side plate is arranged on one side of the top plate;

a second housing fastened to the first housing to form an accommodating chamber for accommodating the host, comprising:

a bottom plate disposed opposite to the top plate; and

the second side plate is arranged on one side of the bottom plate and is opposite to the first side plate;

the top plate and the bottom plate are used for being in a first arc shape with the inner side face matched with the second side plate, the top plate and the bottom plate are in a second arc shape with the outer side face matched with the first side plate, and the bending degree of the second arc is larger than that of the first arc.

2. The protective case of claim 1, further comprising:

a first connecting mechanism disposed between the top plate and the second side plate; and

the second connecting mechanism is arranged between the bottom plate and the first side plate; the first and second connecting mechanisms enable the first and second housings to cooperate to form the accommodating chamber.

3. The protective case of claim 2, wherein the first connection mechanism is a snap connection, a threaded connection, or an adhesive connection; and the second connecting mechanism is a snap connecting structure, a threaded connecting structure or a bonding structure.

4. The protective case of claim 1, further comprising:

and the cover plate is arranged on the top plate and used for covering the top plate.

5. The protective case of claim 4, wherein the surface of the cover plate facing the top plate is provided with a convex pillar, the top plate is provided with a through hole, and the convex pillar on the cover plate is inserted into the through hole.

6. The protective case of claim 4 or 5, wherein the first side plate includes a ridge extending from the top plate in a direction away from the bottom plate; the cover plate is placed in a space defined by the top plate and the ridge portion.

7. The protective case of claim 6, wherein the cover plate is in the first arc shape toward a side of the second side plate and in the second arc shape toward a side of the first side plate.

8. The protective case of claim 1, wherein a boss is fixed to each end of the protective case and located between the first side plate and the second side plate.

9. The protective case of claim 1, further comprising:

a face mask having an upper portion connected to and overlying the first side panel and a lower portion extending beyond the bottom panel.

10. The protective case of claim 9, further comprising:

the rear cover is connected with the lower part of the mask and is positioned below the bottom plate, and a protective space is formed between the rear cover and the lower part of the mask.

11. A protective case for housing a host of head-mounted devices, the protective case comprising:

a first housing comprising:

a top plate; and

the first side plate is arranged on one side of the top plate;

the second casing, with first casing lock includes:

a bottom plate disposed opposite to the top plate; and

the second side plate is arranged on one side of the bottom plate and is opposite to the first side plate;

a first connecting mechanism disposed between the top plate and the second side plate; and

the second connecting mechanism is arranged between the bottom plate and the first side plate; the first connecting mechanism and the second connecting mechanism enable the first shell and the second shell to be matched to form a containing chamber for containing the host.

12. The protective case of claim 11, further comprising:

the cover plate is arranged on the top plate and used for covering the top plate;

wherein the first side plate comprises a ridge extending from the top plate in a direction away from the bottom plate; the cover plate is placed in a space defined by the top plate and the ridge portion.

13. A head-mounted device, comprising:

a protective housing comprising:

a first housing comprising:

a top plate; and

the first side plate is arranged on one side of the top plate;

the second casing, with first casing lock to form the accommodation chamber who is used for holding the host computer, include:

a bottom plate disposed opposite to the top plate; and

the second side plate is arranged on one side of the bottom plate and is opposite to the first side plate;

the tightness adjusting mechanism is arranged opposite to the protective shell;

a lace assembly connecting two ends of the protective housing and opposite ends of the slack adjuster mechanism to form a looped frame, the lace assembly configured to extend into the slack adjuster mechanism such that the slack adjuster mechanism adjusts the length of the lace assembly; and

and the stress assembly is arranged on the annular frame.

14. The headset of claim 13, wherein the strap assembly includes two headbands, the slack adjustment mechanism adjusting the overlap length of the two headbands.

15. The headset of claim 14, wherein each headband includes a heat sink extending from the headband into the protective housing.

16. The head-mounted apparatus according to claim 14 or 15, wherein the two ends of the protection casing are respectively fixed with a convex pillar located between the first side plate and the second side plate, and the end of each headband connected with the protection casing is provided with a connecting hole, and the convex pillar passes through the connecting hole.

17. The headset of claim 13, wherein the force receiving component comprises:

the first stress piece is connected with the protective shell and is positioned on one side of the annular frame; and

and the second stress piece is connected with the tightness adjusting mechanism and is positioned on the other side of the annular frame.

18. The headset of claim 17, further comprising:

the adjustable structure is formed between the protection shell and the first stress piece, so that the horizontal position of the first stress piece relative to the protection shell can be adjusted.

19. The headset of claim 18, wherein the first force bearing comprises:

the mounting plate is used for being connected with the protective shell and is provided with an adjustable through hole so that the mounting plate can be adjusted in position relative to the protective shell along the direction of the adjustable through hole;

the supporting plate extends from one side of the mounting plate; and

the cushion, install in the backup pad, wherein cushion and adjustable through-hole are located respectively the relative both sides of backup pad.

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