CN113315893B - Video camera and video apparatus - Google Patents

Abstract

The application provides a camera and video equipment. The video device includes the camera. The camera comprises a body shell, a bracket, a lens component assembled on the bracket and a side cover. The body shell is provided with a containing cavity, a mounting opening and a lens hole which are communicated, and the mounting opening is formed at least one end of the body shell. The bracket and the lens component are arranged in the accommodating cavity of the machine body shell from the mounting opening, the lens component comprises a lens, and the lens is opposite to the lens hole. The side cover covers the mounting opening and is connected with the support, and the support, the side cover and the machine body shell are relatively fixed. The camera provided by the application is of an integrated structure, does not have a dividing line formed during assembly of a split structure, is only connected with the side cover at the end part, ensures the integrity and the completeness of the appearance of the shell of the camera body, and improves the quality of products.

Description

Video camera and video apparatus

Technical Field

The application relates to the technical field of monitoring, in particular to a camera and video equipment.

Background

Some cameras have obvious boundaries from the appearance structure, for example, the camera housing includes a front housing and a rear housing, and the boundary exists at the connection position of the front housing and the rear housing, which makes the overall sense of the camera weak and causes lower product quality.

Disclosure of Invention

The application provides an improved video camera and video equipment.

A video camera, comprising:

the lens comprises a body shell, a lens and a lens, wherein the body shell is provided with a containing cavity, a mounting opening and a lens hole which are communicated, and the mounting opening is formed at least one end of the body shell;

the lens assembly comprises a lens, and the lens is opposite to the lens hole; and

The side cover covers the mounting opening and is connected with the support, and the support, the side cover and the machine body shell are relatively fixed.

Optionally, the fuselage shell includes the guide structure of locating the internal surface of tip, the support includes the guide cooperation structure, the guide structure with guide cooperation structure sliding fit or rolling fit are used for guiding the support follow the installation mouth cartridge in the house intracavity of fuselage shell.

Optionally, one of the guiding structure and the guiding matching structure comprises a guide rail, the other one of the guiding structure and the guiding matching structure comprises a guide rail groove, the guide rail is in sliding fit with the guide rail groove, the guide rail is arranged in a segmented mode and comprises a first guide rail and a second guide rail which are distributed at intervals, the first guide rail is correspondingly arranged at one end of the guide rail groove in the extending direction, and the second guide rail is correspondingly arranged at the other end of the guide rail groove in the extending direction.

Optionally, the mounting hole includes a first mounting hole formed in one end of the body casing and a second mounting hole formed in the other end of the body casing, the first mounting hole is opposite to the second mounting hole, the side cover includes a first side cover and a second side cover, the first side cover covers the first mounting hole, corresponds to the support frame, is connected with one end of the first mounting hole, the second side cover covers the second mounting hole, corresponds to the support frame, is connected with one end of the second mounting hole, and is arranged to be capable of being inserted into the accommodating cavity from the first mounting hole and the second mounting hole.

Optionally, the lens assembly includes a main board, the camera includes a heat dissipating assembly accommodated in the accommodating cavity, the heat dissipating assembly contacts with the main board and the body housing, so as to transfer heat of the main board to the body housing, and the side cover is configured to apply a force to the heat dissipating assembly, so that the heat dissipating assembly keeps contact with the body housing.

Optionally, the side cover includes an abutment plate extending into the accommodating cavity, the abutment plate abuts against the heat dissipation component, and the acting force is applied to the heat dissipation component.

Optionally, the heat dissipation subassembly includes heat dissipation panel beating and heat conduction pad, the heat dissipation panel beating including form in the contact portion of mid portion with form in the deformable portion of tip, the heat conduction pad assemble in deformable portion towards one side of fuselage shell, contact portion with the mainboard contact, under free state, deformable portion is to keeping away from one side perk of fuselage shell under effort, deformable portion is to being close to one side deformation of fuselage shell, the heat conduction pad with the laminating of fuselage shell.

Optionally, the camera including assemble in the TOF subassembly of support, the TOF subassembly with the mainboard electricity is connected, gives the mainboard input signal, the mainboard is according to the signal adjustment of TOF subassembly input the focus of camera lens, the internal surface of fuselage shell is equipped with supplies the TOF subassembly is with the support is loaded into the mounting groove of acceping the chamber, the fuselage shell is including allowing the TOF subassembly is transmitted optical signal with receive optical signal's signal transmission position, when the camera lens is aimed at the camera lens hole, the TOF subassembly is aimed at signal transmission position.

Optionally, the body housing includes a transmission hole provided at an outer surface and communicating with the installation groove, and a transmission plate sealing the transmission hole, and a position of the transmission plate forms the signal transmission part.

A video apparatus comprising:

a display; and

A camera as claimed in any one of the preceding claims, the camera being connected to the display.

The technical scheme provided by the application at least can achieve the following beneficial effects:

the application provides a camera and video equipment comprising the same, wherein a mounting opening is formed at least one end of a body shell, a bracket and a lens assembly are mounted in a containing cavity of the body shell from the mounting opening, a side cover covers the mounting opening and is connected with the bracket, and the bracket, the side cover and the body shell are kept relatively fixed. The camera body shell has no obvious structural boundary in the middle area, and is only connected with the side cover at the end part, so that the integrity and the completeness of the appearance of the camera body shell are ensured, and the product quality is improved.

Drawings

Fig. 1 is a schematic diagram of a video apparatus according to an exemplary embodiment of the present application;

FIG. 2 is a cross-sectional view of a camera shown in an exemplary embodiment of the application;

FIG. 3 is a schematic view of the fuselage shell shown in FIG. 1;

FIG. 4 is a schematic view of an end of a fuselage shell;

FIG. 5 is a schematic view of a bracket;

FIG. 6 is a schematic view of the deformable portion of the heat dissipating assembly in a free state;

FIG. 7 is a schematic illustration of a deformable portion of a heat dissipating assembly under force;

fig. 8 is an exploded view of the video camera shown in fig. 1.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples do not represent all implementations consistent with the application. Rather, they are merely examples of apparatus and methods consistent with aspects of the application.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs. The terms "first," "second," and the like, as used herein, do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. Also, the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one, and the terms "a" and "an" are used individually. "plurality" or "plurality" means two or more. Unless otherwise indicated, the terms "front," "rear," "lower," and/or "upper," "top," "bottom," and the like are merely for convenience of description and are not limited to one position or one spatial orientation. The word "comprising" or "comprises", and the like, means that elements or items appearing before "comprising" or "comprising" are encompassed by the element or item recited after "comprising" or "comprising" and equivalents thereof, and that other elements or items are not excluded. The terms "connected" or "connected," and the like, are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect.

Referring to fig. 1, fig. 1 is a schematic diagram of a video apparatus 100 according to an exemplary embodiment of the application.

The video apparatus 100 provided by the application comprises a camera 10 and a display 20, wherein the camera 10 is connected with the display 20. Connections may include two-way connections, physical connections and electrical connections. The camera 10 is used for recording optical images and the display 20 is used for displaying images. The application scene of the video apparatus 100 is not limited, and may be a conference room, a studio, a home, various special environments, and the like.

Referring to fig. 2 and 3, fig. 2 is a cross-sectional view of the camera 10 shown in fig. 1. Fig. 3 shows a schematic view of the fuselage housing 11.

The video camera 10 includes a body housing 11, a bracket 12, a lens assembly 13, and a side cover 14. The body housing 11 is formed with a housing cavity 110, and the body housing 11 is further provided with a lens hole 111 and a mounting port 112 communicating with the housing cavity 110. A mounting opening 112 is formed at least one end of the body housing 11, and a lens hole 111 is formed at a sidewall of the body housing 11. The lens assembly 13 is assembled to the bracket 12, and the bracket 12 and the lens assembly 13 assembled to the bracket 12 may be mounted together, and both are mounted in the housing cavity 110 of the body housing 11 from the mounting opening 112. The lens assembly 13 includes a lens 130, and the lens 130 is disposed opposite to and towards the lens hole 111, so as to avoid blocking the field of view of the lens assembly 13. A light-transmitting plate is assembled at the lens hole 111. The light-transmitting plate may be a light-transmitting glass.

The side cover 14 covers the mounting opening 112, and is connected to the bracket 12 at the mounting opening 112, so that the bracket 12, the side cover 14 and the body housing 11 are kept relatively fixed. In the camera 10, the body shell 11 is of an integral structure, a dividing line formed during assembly of a split structure does not exist, and the side cover 14 is only arranged at the end part and used for shielding the mounting opening 112, so that the integrity and the completeness of the appearance of the body shell 11 are ensured, and the product quality is improved.

In one embodiment, the mounting port 112 includes a first mounting port 1120 formed at one end of the body housing 11 and a second mounting port 1122 formed at the other end of the body housing 11, the first mounting port 1120 being disposed opposite the second mounting port 1122. Accordingly, the side cover 14 includes a first side cover 140 and a second side cover 142, and the first side cover 140 covers the first mounting hole 1120, is connected to the bracket 12 at the first mounting hole 1120 toward the end of the first mounting hole 1120, and is relatively fixed to the body housing 11 and the bracket 12. The second side cover 142 covers the second mounting opening 1122, is connected to the bracket 12 at the second mounting opening 1122 at an end facing the second mounting opening 1122, and is fixed relative to the body housing 11 and the bracket 12. The bracket 12 is provided so as to be attachable to the housing chamber 110 of the body housing 11 from the first attachment port 1120 and the second attachment port 1122. In this scheme, fuselage shell 11 sets up to both ends opening and be hollow tubular structure, and the cavity of well department forms into acceping chamber 110, and support 12 can follow the random end cartridge of fuselage shell 11 in acceping chamber 110, has realized the diversification of support 12 mounting form. In this embodiment, the structure of the body housing 11 at the first mounting port 1120 and the structure at the second mounting port 1122 are substantially the same. The first and second side covers 140 and 142 are substantially identical in structure.

Referring to fig. 4 and 5, fig. 4 is a schematic view of the end of the fuselage housing 11. Fig. 5 shows a schematic view of the bracket 12.

In one embodiment, the body housing 11 includes a guide structure 113 provided on an inner surface of the end portion, and the bracket 12 includes a guide engaging structure 120, and the guide structure 113 is slidably engaged or rollably engaged with the guide engaging structure 120, so as to guide the bracket 12 to be inserted into the receiving cavity 110 of the body housing 11 from the first mounting hole 1120. It can be seen that, by the cooperation of the guide structure 113 and the guide cooperation structure 120, the accuracy of the relative position of the bracket 12 and the body housing 11 in the installation process can be improved, and the smoothness in the installation process can be improved, so that the quick installation can be realized. The guiding structure 113 and the guiding matching structure 120 can be respectively provided with a plurality of groups, which are in one-to-one correspondence, so that the stability and the stressed balance in the guiding process are improved. In this embodiment, the guide structure 113 is provided with two sets, respectively provided on two opposite inner surfaces of the body housing 11. Correspondingly, the guiding matching structure 120 is provided with two groups, and is arranged in one-to-one correspondence with the two groups of guiding structures 113.

The specific embodiments of the guide structure 113 and the guide engaging structure 120 are not limited. In one embodiment, one of the guide structure 113 and the guide mating structure 120 includes a guide rail 1200, and the other includes a guide rail slot 1130, the guide rail 1200 being a sliding fit with the guide rail slot 1130. The guide rail 1200 and the guide rail groove 1130 have simple structures, are convenient to set, and are convenient to process and manufacture. In a specific embodiment, the fuselage housing 11 is provided with guide rail slots 1130 and the cradle 12 is provided with guide rails 1200.

In an alternative embodiment, the guide rail 1200 is arranged in segments, and includes a first guide rail 1200a and a second guide rail 1200b that are distributed at intervals, where the first guide rail 1200a is correspondingly arranged at one end of the guide rail slot 1130 in the extending direction, and the second guide rail 1200b is correspondingly arranged at the other end of the guide rail slot 1130 in the extending direction. That is, the guide rails 1200 are provided separately and respectively at both ends of the extending direction of the guide rail groove 1130, which allows the guide rail 1200 to exert a guiding effect when the holder 12 is loaded into the receiving chamber 110 from either end. On the other hand, the adoption of the first guide rail 1200a and the second guide rail 1200b which are segmented can also shorten the total length of the guide rail 1200, so that the processing difficulty of the guide rail 1200 can be reduced, the straightness deviation is large due to the overlong guide rail 1200, the assembly is affected subsequently, the problem of jamming and the like is easy to cause, and the first guide rail 1200a and the second guide rail 1200b are arranged in a split manner, so that the phenomenon can be avoided.

With continued reference to fig. 2, the lens assembly 13 includes a main board 132 with an image sensor, and the main board 132 is assembled at the rear end of the lens 130. The camera 10 further includes a heat dissipation assembly 15 accommodated in the accommodating cavity 110, where the heat dissipation assembly 15 contacts the main board 132 and the body housing 11, so as to transfer heat of the main board 132 to the body housing 11, thereby implementing heat dissipation of the lens assembly 13. The heat dissipation assembly 15 includes a heat dissipation sheet metal made of a metal material. The heat dissipation assembly 15 may be in contact with the body housing 11 at a plurality of locations to increase a heat dissipation path and increase a heat dissipation rate and improve a heat dissipation effect. The heat dissipation assembly 15 is assembled to the body housing 11 in a non-limited manner.

In addition, in order to ensure reliable contact of the heat sink 15 with the body case 11, the side cover 14 is provided to apply a force to the heat sink 15 to keep the heat sink 15 in contact with the body case 11, so as to enhance the efficiency of heat transfer. In this embodiment, the heat dissipating component 15 contacts the body housing 11 at one end near the first mounting opening 1120 and one end near the second mounting opening 1122, so that the first side cover 140 and the second side cover 142 can apply forces to the corresponding portions of the heat dissipating component 15, respectively, so that the heat dissipating component 15 can be kept in close contact with the body housing 11 at least two portions to accelerate heat transfer. In other embodiments, the heat dissipating assembly 15 may also be in contact with the fuselage housing 11 at more locations.

As shown in fig. 2, in one embodiment, the first side cover 140 includes an abutment plate 1400 extending into the accommodating cavity 110, where the abutment plate 1400 abuts against the heat dissipating component 15, and applies the force to the heat dissipating component 15 to press the heat dissipating component 15 against the body housing 11. Correspondingly, the second side cover 142 includes a pressing plate 1420 extending into the accommodating cavity 110, the pressing plate 1420 abuts against the heat dissipating component 15, and applies the force to the heat dissipating component 15 to press the heat dissipating component 15 against the body housing 11, so that the heat dissipating component 15 is tightly contacted with the body housing 11 at a plurality of positions, and the heat transferring efficiency is improved. In one embodiment, the abutment plate 1400 may tilt toward a side proximate to the heat sink assembly 15, applying force to the heat sink assembly 15 by creating interference upon installation.

Referring to fig. 6 and 7, fig. 6 is a schematic diagram of the heat dissipation assembly 15 in a free state. Fig. 7 is a schematic diagram of the heat dissipating assembly 15 subjected to a force.

In an alternative embodiment, the heat dissipating assembly 15 includes a heat dissipating sheet metal 150 and a heat conducting pad 152, the heat dissipating sheet metal 150 includes a contact portion (not shown) formed at a middle portion and a deformable portion 1500 formed at an end portion, the heat conducting pad 152 is assembled to a side of the deformable portion 1500 facing the body case 11, the contact portion is in contact with the main board 132, and the deformable portion 1500 is used for contact with the body case 11. In a free state, the deformable portion 1500 is tilted to a side away from the body case 11, and the deformable portion 1500 is pressed by the force to deform to a side close to the body case 11, so that the heat conductive pad 152 is bonded to the body case 11. In this embodiment, the deformable portion 1500 is deformed by applying a force to the deformable portion 1500 by interference between the pressing plate 1400 and the deformable portion 1500, and the structure is simple and the installation is convenient. In addition, the heat conductive pad 152 is a flexible member, and the heat conductive pad 152 assembled on the deformable portion 1500 contacts the body housing 11, so that a gap between the heat conductive pad 152 and the body housing 11 can be prevented, thereby further improving the heat transfer effect. The deformable portion 1500 may be formed by bending. The thermal pad 152 may be adhered to the deformable portion 1500.

In one embodiment, the deformable portion 1500 may be at an angle to the horizontal in the free state, such as, but not limited to, 5 °. The thermal pad 152 may leave a predetermined gap, for example, a gap of 0.3mm with the body housing 11 in a free state, but is not limited thereto. By doing so, it is possible to avoid that the friction force at the time of installation is too large to install due to the contact of the heat conductive pad 152 with the body housing 11. Under the action of the force, the deformable portion 1500 is pressed by the pressing plate 1400, the deformable portion 1500 is pressed back to the horizontal, the heat conducting pad 152 is tightly contacted with the body housing 11, and the heat of the lens assembly 13 is conducted to the body housing 11, so that heat dissipation is realized.

Referring to fig. 4, 5 and 8, fig. 8 shows an exploded view of camera 10.

In one embodiment, the two ends of the bracket 12 are configured to have substantially the same structure, and for example, one end of the bracket 12 includes a first end 1202 facing the first side cover 140, the first end 1202 includes a connection post 122, the connection post 122 is formed with a connection hole 1220, and the screw 17 passes through the first side cover 140 and is locked in the connection hole 1220 to fix the first side cover 140 to the first end 1202 of the bracket 12. The body case 11 includes an end surface 114 and a stepped surface 115 formed at the end, the end surface 114 and the stepped surface 115 being distributed in a direction in which the holder 12 is inserted into the receiving chamber 110, and an inner surface of the first side cover 140 abuts against the stepped surface 115, so that the first side cover 140 can be stably supported on the stepped surface 115. Wherein the end surface of the first end 1202 does not protrude from the step surface 115, avoiding installation interference. Alternatively, the distance between the end surface 114 and the step surface 115 may be set to be substantially equal to the thickness of the first side cover 140, and then the outer surface of the first side cover 140 may be substantially flush with the end surface 114.

The bracket 12 includes a second end 1204 facing the second side cover 142, and the second end 1204 has substantially the same structure as the first end 1202 and is connected to the second side cover 142 in substantially the same manner, which is not described herein.

Referring to fig. 2 to 4, the camera 10 includes a TOF (Time of flight) component 16 assembled to the stand 12, the TOF component 16 is electrically connected to the motherboard 132, a signal is input to the motherboard 132, and the motherboard 132 adjusts the focal length of the lens 130 according to the signal input by the TOF component 16. The inner surface of the fuselage housing 11 is provided with mounting slots 116 for the TOF assembly 16 to fit into the receiving cavity 110 with the cradle 12 to avoid interference during installation. The fuselage housing 11 includes a signal transmission region 117 that allows the TOF assembly 16 to transmit optical signals and to receive optical signals, the TOF assembly 16 being aligned with the signal transmission region 117 when the lens 130 is aligned with the lens aperture 111. The TOF assembly 16 achieves auto-focusing of the lens 130, which is beneficial for improving the resolution of the camera 10.

In one embodiment, the body housing 11 includes a transmission hole 118 provided at an outer surface and communicating with the mounting groove 116, and a transmission plate 119 sealing the transmission hole 118, the transmission plate 119 being positioned to form the signal transmission portion 117. The transmitting plate 119 is configured as an infrared transmitting acrylic plate, and may be attached to the body housing 11 by a back adhesive. The distance between the TOF assembly 16 and the transmissive plate 119 is less than 0.5mm. The body housing 11 is formed with a recess 1180 at the outer periphery of the transmission hole 118, the transmission plate 119 is accommodated in the recess 1180, and is adhered to the bottom wall of the recess 1180. The transmission hole 118 is opened at the same side of the body housing 11 as the lens hole 111.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather to enable any modification, equivalent replacement, improvement or the like to be made within the spirit and principles of the application.

Claims (9)

1. A video camera, comprising:

the lens comprises a body shell, a lens and a lens, wherein the body shell is provided with a containing cavity, a mounting opening and a lens hole which are communicated, and the mounting opening is formed at least one end of the body shell;

the lens assembly comprises a lens, and the lens is opposite to the lens hole;

a side cover covering the mounting opening and connected with the bracket, wherein the bracket, the side cover and the machine body shell are kept relatively fixed;

the radiating component is accommodated in the accommodating cavity and is respectively contacted with the lens component and the machine body shell;

the heat dissipation assembly comprises a heat conduction pad and a heat dissipation metal plate, and the heat conduction pad is assembled on one side of a deformable part of the end part of the heat dissipation metal plate, which faces the shell of the machine body; the heat conducting pad is a flexible piece and is in fit contact with the machine body shell so as to fill a gap between the heat conducting pad and the machine body shell; in a free state, the deformable portion is tilted toward a side away from the body housing; under the action of force, the deformable part deforms to the side close to the body shell, so that the heat conducting pad is in close contact with the body shell;

the machine body shell comprises a guide structure arranged on the inner surface of the end part, the support comprises a guide matching structure, and the guide structure is in sliding fit or rolling fit with the guide matching structure and is used for guiding the support to be inserted into the accommodating cavity of the machine body shell from the mounting opening; the guide structures are provided with two groups which are respectively arranged on two opposite inner surfaces of the machine body shell, and the two groups of guide structures are oppositely arranged; correspondingly, the guiding matching structure is provided with two groups, and the two groups of guiding structures are arranged in one-to-one correspondence.

2. The camera of claim 1, wherein one of the guide structure and the guide mating structure includes a guide rail, the other includes a guide rail groove, the guide rail is slidably mated with the guide rail groove, the guide rail is arranged in sections, and includes a first guide rail and a second guide rail that are distributed at intervals, the first guide rail is correspondingly arranged at one end of the guide rail groove in the extending direction, and the second guide rail is correspondingly arranged at the other end of the guide rail groove in the extending direction.

3. The camera according to any one of claims 1 to 2, wherein the mounting port includes a first mounting port formed at one end of the body housing and a second mounting port formed at the other end of the body housing, the first mounting port being opposite to the second mounting port, the side cover including a first side cover and a second side cover, the first side cover covering the first mounting port, being connected to one end of the bracket corresponding to the first mounting port, the second side cover covering the second mounting port, being connected to one end of the bracket corresponding to the second mounting port, the bracket being configured to be insertable into the housing chamber from the first mounting port and the second mounting port.

4. The camera of any one of claims 1 to 2, wherein the lens assembly comprises a main board, the heat sink assembly being in contact with the main board and the body housing for transferring heat from the main board to the body housing, the side cover being arranged to apply a force to the heat sink assembly to maintain the heat sink assembly in contact with the body housing.

5. The camera of claim 4, wherein the side cover includes an abutment plate extending into the receiving cavity, the abutment plate abutting the heat sink assembly to apply the force to the heat sink assembly.

6. The camera of claim 5, wherein the heat dissipating sheet metal includes a contact portion formed at a middle portion and the deformable portion formed at an end portion, the contact portion being in contact with the main board.

7. The camera of claim 4, wherein the camera comprises a TOF assembly assembled to the holder, the TOF assembly is electrically connected to the motherboard, a signal is input to the motherboard, the motherboard adjusts a focal length of the lens according to the signal input by the TOF assembly, an installation groove for the TOF assembly to be installed into the accommodating cavity along with the holder is formed in an inner surface of the body shell, the body shell comprises a signal transmission part allowing the TOF assembly to emit and receive optical signals, and the TOF assembly is aligned with the signal transmission part when the lens is aligned with the lens hole.

8. The camera according to claim 7, wherein the body housing includes a transmission hole provided at an outer surface and communicating with the mounting groove, and a transmission plate sealing the transmission hole, a position of the transmission plate forming the signal transmission portion.

9. A video apparatus, comprising:

a display; and

The camera of any one of claims 1 to 8, connected to the display.