CN207764535U - The more mesh cameras of high-cooling property and its radiator structure - Google Patents
The more mesh cameras of high-cooling property and its radiator structure Download PDFInfo
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- CN207764535U CN207764535U CN201820006868.6U CN201820006868U CN207764535U CN 207764535 U CN207764535 U CN 207764535U CN 201820006868 U CN201820006868 U CN 201820006868U CN 207764535 U CN207764535 U CN 207764535U
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Abstract
The utility model discloses the more mesh cameras of a high-cooling property and its radiator structures, the wherein described more mesh cameras of high-cooling property include mesh camera main-body at least more than one, wherein described more mesh camera main-bodies include an at least wiring board, an and at least radiator structure, the wherein described radiator structure is set to more mesh camera main-bodies, and heat exchange occurs with more mesh camera main-bodies.It is worth mentioning that, the radiator structure reduces the temperature of more mesh camera main-bodies with air-cooled technology, the wherein described radiator structure includes an at least heat dissipation element and at least one air-cooled element, the wherein described air-cooled element is set to the air duct, the temperature of the heat dissipation element is reduced in the form of blowing, the heat dissipation element reduces the temperature of more mesh camera main-bodies.
Description
Technical field
The utility model is related to mesh camera more than one, more particularly to the more mesh cameras of a high-cooling property and its radiator structure, wherein
The more mesh cameras of high-cooling property can be provided simultaneously with the characteristic of small size and high-cooling property.
Background technology
Panorama camera is a kind of more mesh cameras of special applications, and specifically, panorama camera, which is one kind, to pan
More mesh cameras of image or video.Identical with most of more mesh cameras to be, panorama camera includes at least two cameras, complete
In the course of work of scape camera, the plurality of pictures of multiple camera shootings is combined into a Zhang Quanjing picture, or the video of shooting
It is spliced into panoramic video.It will be illustrated below using panorama camera as a typical more mesh cameras.
As the virtual reality device of various consumer levels starts to popularize, user also gradually increases the demand of virtual reality
More, user has been no longer confined to game and short-sighted frequency for the demand of virtual reality, and more users wish through 360 degree of panorama sketch
The form of piece and video records the scene of life.In order to cater to the demand of user, the panorama phase of 360 degree of panorama contents can be generated
Machine initially enters consumer level market.Correspondingly, panorama camera is just developed with the very fast speed of development, specifically, panorama phase
The development of machine from it is initial it is single-lens be developed to more camera lenses, more pixel densities are developed to from low pixel density, from low frame per second
Develop supreme frame per second, splicing from the outside is developed to splicing in machine, and small size is developed to from large volume, and these changes need panorama
Camera internal configures corresponding high-resolution, the image processing unit of high response and high performance CPU element, image procossing list
Member or the data of CPU calculate the fever that can cause panorama camera.Or it can be said that panorama camera towards the high property of high aggregation degree
The direction of energy is developed, but the thing followed is exactly heating problem caused by the big power consumption of panorama camera.
Specifically, when panorama camera is arranged a camera lens more or improves the quality of data, the panorama camera
The operating pressure of image processing unit correspondingly increases, these image processing units need Quick Acquisition and operation additionally to be increased
Data volume, be enhanced so as to cause the power consumption of panorama camera, further cause the heating problem of panorama camera.In addition, being
Meets the needs of actual scene, panorama camera just develops towards the high performance direction of small size, this means that panorama camera
Available inner space is compressed further, and the inner working components of panorama camera are arranged in a manner of overall compact,
This also means that the heat-dissipating space of panorama camera becomes smaller.Whether volume becomes smaller or power consumption becomes larger and results in the list of panorama camera
The power density of elementary volume becomes larger, to be further exacerbated by the heating problem of panorama camera.And the fever of panorama camera can pole
The working performance of the inner working components of panorama camera is influenced to big degree, in other words, the panorama camera of height fever has operation
Unstable and flimsy problem, this dramatically affects the popularization and application of panorama camera.
In order to solve the heating problem of panorama camera, mainly solved on the market using following two modes at present, but this
There are more or less defects for both of which:
First way wraps up mesh camera main-body more than one using metal shell.It is well known that metal has conductive force,
When metal shell is for when wrapping up more mesh camera main-bodies, the heat of more mesh camera main-bodies can to pass through the metal shell
It is exported, in other words, the metal shell carries out heat exchange with more mesh camera main-bodies, to reduce more mesh phase owners
The temperature of body.However, when the metal shell is applied to radiate more mesh camera main-bodies, the metal shell can be caused
There are hot phenomenons for itself, when user directly touches the metal shell, exist and the safety problems such as are burned, when more mesh
When camera is applied to electronic equipment, the high temperature of the metal shell can influence the workability for the element that other are contacted therewith
Energy.
The second way, by the way of increasing on radiation tooth in shell.Shell with radiation tooth is applied to wrap up
The heat of mesh camera main-body more than one, more mesh camera main-bodies can be dispersed into the external world by the radiation tooth, i.e., described more mesh phases
By the radiation tooth with extraneous heat exchange can occur for owner's body.However, the mode for increasing radiation tooth on the shell undoubtedly can
Increase the volume of shell and more mesh cameras, and the appearance for influencing more mesh cameras is aesthetic.It is dissipated in addition, increasing on the shell
The heat dissipation effect of the mode of hot tooth is simultaneously bad, and can cause part more mesh camera main-bodies that can directly be connect with external environment
It touches, the dirt of external environment may pollute more mesh camera main-bodies into more mesh camera main-bodies at this time.
In conclusion how to ensure more mesh cameras while small size, improve its thermal diffusivity, be more in the prior art
The big problem that must be faced and solve in the evolution of mesh camera.
Invention content
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
The more mesh cameras of high-cooling property complete the heat dissipation of more mesh cameras by air-cooled technology, in other words, the more mesh camera productions of high-cooling property
Raw heat is cooled by air-cooled technology.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
The more mesh cameras of high-cooling property it is more can to improve the high-cooling property while not increasing the volume of the more mesh cameras of the high-cooling property
The thermal diffusivity of mesh camera.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein application
It is designed to special shape in the radiator structure of the more mesh cameras of the high-cooling property, the radiator structure effectively prevent hot-air to fall
The appearance of flow phenomenon ensure that the high-cooling property of the more mesh cameras of the high-cooling property by this method.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
Radiator structure is separately set in mesh camera main-body more than one, the work in the air duct and more mesh camera main-bodies that the radiator structure is formed
It is mutually separated as element, to ensure the optical property of more mesh camera main-bodies.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
Radiator structure radiates to more mesh camera main-bodies using air-cooled technology, improves the heat dissipation of the more mesh cameras of the high-cooling property
Property and radiating efficiency.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
Radiator structure is assembled and is formed by an at least heat dissipation element and at least one air-cooled element, difficult with the production for reducing the radiator structure
Degree improves production efficiency while reducing production cost.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
The air-cooled element of radiator structure is removably assembled in the heat dissipation element, in order to the repair of the radiator structure, and
Extend the service life of the more mesh cameras of the high-cooling property.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
The more mesh cameras of high-cooling property use plastic material shell, to prevent unnecessary scald caused by shell overheat, raising user
User experience, and reduce the weight of the more mesh cameras of the high-cooling property.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
The more mesh cameras of high-cooling property are small, can economical space saving be applied to the special screne of polymorphic type, such as a series of insertion
End formula.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
The thermal diffusivity of the more mesh cameras of high-cooling property is strong, and in other words, the radiator structure radiating efficiency is high, to protect more mesh cameras
Main body extends the service life of the more mesh cameras of the high-cooling property.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
Radiator structure is easy to assembly, to reduce the assembling difficulty of the more mesh cameras of the high-cooling property, and reduces the more mesh of the high-cooling property
The manufacturing cost of camera.
One of the utility model is designed to provide the more mesh cameras of a high-cooling property and its radiator structure, wherein described
Radiator structure has a wide range of application, and can be applied to more mesh cameras of polymorphic type, and the more mesh cameras of the high-cooling property are formed with assembling.
In order to reach any of the above goal of the invention, the utility model provides the more mesh cameras of a high-cooling property, is applied to
Radiate mesh camera main-body at least more than one, wherein more mesh camera main-bodies include an at least wiring board, an at least operation element quilt
It is set to the wiring board, including:
An at least heat dissipation element, wherein the heat dissipation element is equipped with an at least air outlet, wherein the air outlet is set to
The top side of the heat dissipation element, and the air outlet forms an air duct inside the heat dissipation element;And
At least one air-cooled element reduces described dissipate wherein the air-cooled element is set to the air duct in the form of blowing
The temperature of thermal element, the heat dissipation element are set to more mesh camera main-bodies, and heat exchange occurs with more mesh camera main-bodies.
In some embodiments, the heat sink body contacts the operation element, heat exchange occurs with the operation element.
In some embodiments, an at least heat-conducting medium is set between the heat sink body and the wiring board, wherein described
Heat-conducting medium thermal conductivity leads to the heat sink body and the operation element.
In some embodiments, wherein at least one heat dissipation groove of side surface setting of the heat dissipation element, wherein described dissipate
Hot groove increases the surface area of the heat dissipation element.
In some embodiments, wherein the heat dissipation groove is implemented as a series of radiation tooths, and the radiation tooth is described
The side surface of heat sink body is recessed inwardly.
In some embodiments, wherein the heat dissipation element is internally provided at least one air-cooled chamber, wherein the air-cooled chamber is logical
It crosses the air outlet and heat exchange occurs with external environment, wherein the air-cooled element is set to the air-cooled chamber, wherein the wind
The accommodating volume of cold chamber is not less than the volume of the air-cooled element.
In some embodiments, wherein the air-cooled element is detachably secured to described by an at least tightening member
Air-cooled chamber.
In some embodiments, wherein the thermal conductivity of the heat-conducting medium is more than the thermal conductivity of air dielectric.
In some embodiments, wherein the heat dissipation element is prepared by a Heat Conduction Material.
In some embodiments, wherein the air-cooled element is implemented as a fan.
According to another aspect of the present invention, the present invention provides the more mesh cameras of a high-cooling property, which is characterized in that including:
Mesh camera main-body at least more than one, wherein more mesh camera main-bodies include an at least wiring board, at least two camera lenses,
Described in camera lens by the wiring board work support, at least an operation element is set to the wiring board;And
An at least radiator structure, wherein the radiator structure is set to more mesh camera main-bodies, with more mesh camera main-bodies
Heat exchange occurs;
The wherein described radiator structure includes an at least heat dissipation element and at least one air-cooled element, wherein the heat dissipation element
Equipped with an at least air outlet, wherein the air outlet is set to the top side of the heat dissipation element, and the air outlet is in institute
It states and forms an air duct inside heat dissipation element;The wherein described air-cooled element is set to the air duct, in the form of blowing described in reduction
The temperature of heat dissipation element.
In some embodiments, wherein the more mesh cameras of high-cooling property further comprise a protective cover, wherein the guarantor
Shield defines a protection chamber, and the radiator structure and more mesh camera main-bodies are arranged at the protection intracavitary and are protected.
In some embodiments, wherein the protection chamber defines an at least heat dissipation chamber and an at least camera chamber, wherein institute
The volume for stating heat dissipation chamber adapts to the radiator structure, so that when the radiator structure is set to the heat dissipation chamber, it is described
The outer surface of radiator structure fits in the inner surface of the heat dissipation chamber.
In some embodiments, wherein an at least tuyere notch is arranged in the protective cover, wherein the shape of the tuyere notch is big
Small and quantity adapts to the air port of the radiator structure.
In some embodiments, wherein an at least heat emission hole is arranged in the protective cover, wherein the shape of the heat emission hole is big
Small and quantity adapts to the heat dissipation groove of the radiator structure.
Description of the drawings
Fig. 1 is the structural schematic diagram of the more mesh cameras of high-cooling property of an embodiment according to the present utility model.
Fig. 2 is the exploded perspective view of the more mesh cameras of the high-cooling property of above-described embodiment according to the present utility model,
Described in the more mesh cameras of high-cooling property include a radiator structure, the camera main-body of mesh more than one and a protective cover.
Fig. 3 is the structural schematic diagram of the radiator structure of above-described embodiment according to the present utility model.
Fig. 4 is the schematic cross-section of the radiator structure of above-described embodiment according to the present utility model.
Fig. 5 is the radiating principle figure of the radiator structure of above-described embodiment according to the present utility model.
Fig. 6 is the structural schematic diagram of more mesh camera main-bodies of above-described embodiment according to the present utility model.
Fig. 7 is that the radiator structure of above-described embodiment according to the present utility model is assembled in more mesh camera main-bodies
Structural schematic diagram.
Fig. 8 is that the radiator structure of above-described embodiment according to the present utility model is ridden upon more mesh camera main-bodies
Close-up schematic view.
Fig. 9 is the radiator structure of an equivalent embodiment of above-described embodiment according to the present utility model by riding upon
State the partial enlarged view of more mesh cameras.
Figure 10 is the structural schematic diagram of the protective cover of above-described embodiment according to the present utility model.
Figure 11 is that the radiator structure of above-described embodiment according to the present utility model is arranged at cutting for the protective cover
Face schematic diagram.
Figure 12 is the more mesh camera applications of the high-cooling property of above-described embodiment according to the present utility model in a built-in end
The operating diagram of formula.
Specific implementation mode
It is described below for disclosing the utility model so that those skilled in the art can realize the utility model.It retouches below
Preferred embodiment in stating is only used as illustrating, it may occur to persons skilled in the art that other obvious modifications.It is retouched following
The basic principle of the utility model defined in stating can be applied to other embodiments, deformation scheme, improvement project, etc. Tongfangs
The other technologies scheme of case and spirit and scope without departing from the utility model.
It will be understood by those skilled in the art that in the exposure of the utility model, term " longitudinal direction ", " transverse direction ", "upper",
The orientation of the instructions such as "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom" "inner", "outside" or position are closed
System is to be based on the orientation or positional relationship shown in the drawings, and is merely for convenience of describing the present invention and simplifying the description, without
It is instruction or implies that signified device or element must have a particular orientation, with specific azimuth configuration and operation, therefore on
Term is stated to should not be understood as limiting the present invention.
It is understood that term " one " is interpreted as " at least one " or " one or more ", i.e., in one embodiment,
The quantity of one element can be one, and in a further embodiment, the quantity of the element can be multiple, and term " one " is no
It can be interpreted as the limitation to quantity.
As depicted in figs. 1 and 2, the more mesh cameras of the high-cooling property of an embodiment according to the present utility model 1 are demonstrated, described
The more mesh cameras 1 of high-cooling property include a protective cover 10, a radiator structure 2 and the camera main-body of mesh more than one 40, wherein the heat dissipation
Structure 2 is arranged at more mesh camera main-bodies 40, provides cooling effect for more mesh camera main-bodies 40, the in addition heat dissipation
Structure 2 and more mesh camera main-bodies 40 are placed in the protective cover 10 and are protected.
It is noted that the more mesh cameras of the high-cooling property 1 have both the advantage of small size and high-cooling property simultaneously, or
It says, the more mesh cameras of the high-cooling property 1 have high-cooling property while ensureing small size, so that the high-cooling property is more
Mesh camera 1 has practical application in more special screnes.An embodiment according to the present utility model, the utility model will be air-cooled
Technology is applied in more mesh cameras of compact, is dissipated to be effectively improved it in the case where not changing more mesh camera volumes
Thermal energy power and job stability.
It is noted that more mesh cameras are implemented as including multiple cameras or multiple camera shootings simultaneously as mentioned herein
The equipment of head will be illustrated so that more mesh cameras are implemented as a panorama camera as an example in the present invention, but be familiar with
The people of this technology should be understood that more mesh cameras can be implemented as other electronic equipments, and the utility model is in this respect simultaneously
It is unrestricted.
An embodiment according to the present utility model, the radiator structure 2 include an at least heat dissipation element 20 and at least one
Air-cooled element 30, wherein the air-cooled element 30 is arranged at the heat dissipation element 20, to form the radiator structure 2, wherein
The radiator structure 2 is arranged at more mesh camera main-bodies 40, with the more mesh camera main-bodies 40 that cool down.
It is well known that most of electronic equipment can all have fever after the state of devoting oneself to work, and in other words, electricity
Sub- equipment at work can convert the energy of a part to heat, and more mesh camera main-bodies 40 are also inevitable at work
There is fever in ground.However, more mesh camera main-bodies 40 are as a kind of high-accuracy electronic equipment, more mesh cameras
The fever of main body 40 can largely influence the working performance of more mesh camera main-bodies 40.Specifically, more mesh
The fever of camera main-body 40 can directly or indirectly lead to more 40 fluctuations of service of mesh camera main-body and damage, to directly
Influence the use of people.Therefore in the practical application of more mesh camera main-bodies 40, the fever of more mesh camera main-bodies 40 is
Urgent problem to be solved.
In an embodiment of the utility model, the more mesh cameras of the high-cooling property 1 are radiated by air-cooled technology, are had
For body, the heat dissipation element 20 contacts more mesh camera main-bodies 40, and certainly, the heat dissipation element 20 is implemented as a heat conduction
Material, when the heat dissipation element 20 contacts more mesh camera main-bodies 40, the heat dissipation element 20 and more mesh phase owners
Heat exchange occurs for body 40, i.e. the temperature of more mesh camera main-bodies 40 is transmitted to the heat dissipation element 20.The air-cooled element
30 reduce the temperature of the heat dissipation element 20 in the form of blowing, and in other words, the air-cooled element 30 accelerates the heat dissipation element
20 with the heat exchange of external environment, to accelerate the cooling of the heat dissipation element 20.When the temperature of the heat dissipation element 20 is dropped
After low, the heat dissipation element 20 can continue that heat exchange occurs with more mesh camera main-bodies 40, improve more mesh by this method
The cooling efficiency of camera main-body 40.
As shown in figure 3, the heat dissipation element 20 includes a heat sink body 21, wherein the heat sink body 21 is implemented as one
Heat carrier, in other words, the part or all of heat dissipation element 20 are prepared by a Heat Conduction Material 210.The heat sink body 21
More mesh camera main-bodies 40 are arranged at, and contact more mesh camera main-bodies 40, to be sent out with more mesh camera main-bodies 40
Raw heat exchange, so that the heat of more mesh camera main-bodies 40 can be dispersed by the heat sink body 21.
Specifically, a heat dissipation bottom surface 211 of the heat sink body 21 contacts more mesh camera main-bodies 40, heat is occurring
When conduction, heat can be conducted from the side of high heat towards the side of low energy, i.e., when a high temp objects and a low temperature object
When body contacts, the energy of the high temp objects can be conducted to the cryogenic object, so that the temperature of two objects is finally supported
Up to the state of relative equilibrium, the temperature of the high temp objects can be reduced by this method, and increases the temperature of the cryogenic object.
In the embodiments of the present invention, more mesh camera main-bodies 40 will produce certain energy after a period of operation, to
The temperature of more mesh camera main-bodies 40 is caused to increase, heat is conducted to relatively by more mesh camera main-bodies 40 of relatively-high temperature
The heat sink body 21 of low temperature, to reduce the temperature of more mesh camera main-bodies 40.
It is worth noting that, in an embodiment of the utility model, the heat sink body 21 is implemented as by metal material
Matter is prepared, but the people for being familiar with this technology should be understood that the heat sink body 21 can be implemented as it is any other have it is good
The material preparation of good thermal conductivity forms, and the utility model is unrestricted in this regard.
However when the temperature of more mesh camera main-bodies 40 is lowered by the heat dissipation element 20, when heat dissipation member
When the temperature of part 20 is finally close or is equal to the temperature of more mesh camera main-bodies 40, more mesh camera main-bodies 40 dissipate
The thermal efficiency reduces.In order to improve the radiating efficiency of more mesh camera main-bodies 40, the radiator structure 2 further comprises the wind
Cold element 30, wherein the air-cooled element 30 reduces the temperature of the heat dissipation element 20 with air-cooled technology-forcing, the institute to be cooled down
It states heat dissipation element 20 to continue to complete heat transfer with more mesh camera main-bodies 40, to improve the drop of more mesh camera main-bodies 40
Warm efficiency.
In order to house the air-cooled element 30, the heat dissipation element 20 forms an air-cooled chamber 200, wherein described air-cooled
Element 30 is arranged in the air-cooled chamber 200, to force to reduce the temperature of the heat dissipation element 20.Specifically, in this reality
With in a novel embodiment, the air-cooled element 30 is implemented as a blowing element, such as fan, wind turbine etc., described air-cooled
The people that element 30 is reduced the temperature of the heat dissipation element 20 in a manner of blowing, but is familiar with this technology should be understood that the wind
The type and structure of cold element 30 are unrestricted.
It is noted that the air-cooled element 30 can self-powered realize to the air-cooled of the heat dissipation element 20, can also lead to
External power supply is crossed to realize to the air-cooled of the heat dissipation element 20.When the air-cooled element 30 realizes wind by the form of external power supply
When cold, 30 surface of the air-cooled element setting, one external energy source, the external energy source external power supply is with for the air-cooled member
Part 30 provides energy and supports.
Specifically, when the radiator structure 2 is set to more mesh camera main-bodies 40, the institute of the heat dissipation element 20
It states heat dissipation bottom surface 211 and contacts more mesh camera main-bodies 40, the top side of the heat dissipation element 20 is provided with the air-cooled chamber 200, institute
It states air-cooled element 30 to be placed in the air-cooled chamber 200, to realize the forced cooling to the heat dissipation element 20.
The heat dissipation element 20 forms an at least air port, specifically, the top side of the heat dissipation element 20 forms at least one
Air outlet 232.The utility model will be illustrated by taking 20 1 air outlets 232 of the heat dissipation element as an example, but not as limitation.
When the heat dissipation element 20 forms the air outlet 232, correspondingly, the top side of the air-cooled chamber 200 is provided with
One first chamber opening 201, so that the thermal current in the air-cooled chamber 200 can be open 201 outward by first chamber
Diverging.It is worth noting that, the first chamber opening 201 is set to the top side of the air-cooled chamber 200, so that positioned at described
Air-flow in air-cooled chamber 200 can drive hot-air to be flowed outwardly from first chamber opening 201.
The heat dissipation element 20 forms the first chamber opening 201, to define an air duct inside the heat dissipation element 20
300.In other words, the heat dissipation element 20 is run through in the air duct 300, so that an outer end air-flow can pass through the air duct 300, and
The heat dissipation element 22 is cooled down in time.Wherein, the first chamber opening 201 is implemented as the air outlet 232, outer end low temperature gas
Stream enters the air duct 300, and heat exchange occurs with the heat dissipation element 20, the final outer end air-flow is with a high temperature gas flow
Form enters the air duct 300 from the flowing outward of second chamber opening 202, completely new outer end low-temperature airflow.It is worth mentioning
It is that in the embodiments of the present invention, the low temperature and the high temperature are relative concept, when the gas flow temperature is not higher than
At this time when the temperature of the heat dissipation element 20, the air-flow is defined as the low-temperature airflow, when the gas flow temperature is higher than
When the cryogenic temperature, the air-flow is defined as the high temperature gas flow.In addition, the outer end air-flow can be implemented as air Jie
Matter or any other medium that heat exchange can occur with the heat dissipation element 20.
In order to further improve the radiating efficiency of the heat dissipation element 20, the air-cooled element 30 is arranged at described dissipate
Inside thermal element 20, specifically, the air-cooled element 30 is arranged at the air-cooled chamber 200, the air-cooled chamber 200 is set to
The air duct 300, wherein the area of the air-cooled chamber 200 is not more than the area in the air duct 300.
When the air-cooled element 30 is arranged at the air-cooled chamber 200, the air-cooled element 30 forces blowing, to accelerate
The flow rate of the outer end air-flow.Specifically, the air-cooled element 30 can drive the outer end air-flow with faster rate
It is dissipated outward from the air outlet 232, and exchanges the temperature of the heat dissipation element 20.In some embodiments, described air-cooled
Element 30 can voluntarily generate air-flow, to accelerate the heat exchange process of the heat dissipation element 20.
What is particularly worth mentioning is that in an embodiment of the utility model, the air-cooled element 30 is arranged at described
The symmetric position of heat dissipation element 20, symmetrically to accelerate the air duct 300, internally air-flow flows, and improves described dissipate by this method
The radiating efficiency of thermal element 20.
As shown in figure 5, an outer end air-flow enters the air-cooled chamber 200, and flowed out from the air outlet 232, it is described air-cooled
The presence of element 30 accelerates the flowing of the outer end air-flow, and then improves the radiating efficiency of the heat dissipation element 20.Certainly,
The air-cooled element 30 can self-produced angry stream, the air-flow still flows outwardly from the air outlet 232.
By first chamber opening 201 with external environment air-flow occurs for the air-cooled chamber 200 described in other words of the air duct 300
It exchanges, in other words, heat dissipation element 20 and external environment described in 232 unicom of the air outlet.When the outer end air-flow is dissipated with described
After heat exchange occurs for thermal element 20, thermal current is from the air outlet 232 to external diffusion.
In addition, the air-cooled element 30 in a variety of forms and can be fixed on the air-cooled chamber 200, the one of the utility model
In embodiment, the air-cooled element 30 is fixed in by a tightening member in the air-cooled chamber 200.In the another of the utility model
In one embodiment, the air-cooled element 30 is detachably secured to the air-cooled chamber 200, in order to the group of the radiator structure 2
Dress and repair.Specifically, when the air-cooled element 30 breaks down, maintenance personal only can replace or repair the air-cooled member
Part 30, without replacing entire cooling structure 2.In addition, 20 separable assembled of the air-cooled element 30 and the heat dissipation element,
The form of fission production also greatly reduces the production difficulty and production cost of the radiator structure 2.
In order to further increase the heat exchange area of the heat dissipation element 20, the heat dissipation element 20 further comprises at least
One heat dissipation groove 22, wherein the heat dissipation groove 22 is arranged at the side surface of the heat dissipation element 20, in the utility model
In one embodiment, the heat dissipation groove 22 is implemented as a radiation tooth, certainly, be familiar with this technology people should be understood that it is described
The type and structure of heat dissipation groove 22 are unrestricted.
The setting of the heat dissipation groove 22 substantially increases the heat exchange area of the heat dissipation element 20, and effectively subtracts
The light volume and weight of the radiator structure 2.When the heat dissipation element 20 and the more mesh camera main-bodies 40 complete heat exchanges,
The temperature of the heat dissipation element 20 can preferably be exchanged by the heat dissipation groove 22.Also, the heat dissipation groove 22 may be used also
Increase the heat exchange area of the heat dissipation element 20 and more mesh camera main-bodies 40, in other words, the heat dissipation groove 22 increases
The surface area of the heat dissipation element 20 so that the heat for arriving at the heat dissipation element 20 have the area of bigger by diffusion and
It is exchanged, by this method, increases the radiating efficiency of the heat dissipation element 20 while not increasing 2 volume of radiator structure.
As shown in Figure 6 and Figure 7, when the heat dissipation element 20 is arranged at more mesh camera main-bodies 40, the heat dissipation
Bottom surface 211 contacts the heater element of more mesh camera main-bodies 40, so that the high temperature of more mesh camera main-bodies 40 passes through
The heat dissipation element 20 is exchanged.
In an embodiment of the utility model, more mesh camera main-bodies 40 are implemented as mesh panorama camera more than one, institute
State more mesh camera main-bodies 40 include a holder 41, at least two camera lenses 42 and a wiring board 43, wherein the camera lens 42 respectively by
The both sides of the holder 41 are set to, the wiring board 43 is set to the top side of the holder 41, wherein the camera lens 42 passes through
41 Electricity Federation of the holder passes through the wiring board 43, is supported so that the camera lens 42 can be worked by the wiring board 43.
Specifically, in the embodiments of the present invention, more mesh camera main-bodies 40 are implemented as a binocular camera
Main body, more mesh camera main-bodies 40 include two camera lenses 42, and certainly, the number amount and type of the camera lens 42 are unrestricted, institute
The different location that camera lens 42 is arranged at the holder 41 is stated, so that a plurality of lenses 42 can start work in different angle simultaneously
Make.The wiring board 43 is also arranged at the holder 41, and in the embodiments of the present invention, the wiring board 43 is set
In the top side of the holder 41, but the people for being familiar with this technology should be understood that the utility model is unrestricted in this regard.
Supportive body of the wherein described holder 41 as more mesh camera main-bodies 40, to support the camera lens 42 and institute
State wiring board 43, the camera lens 42 by electric wire or other modes unicom in the wiring board 43 so that the camera lens
42 can be controlled by the wiring board 43, and are supported.
In addition, an at least operation element 431 is arranged on the wiring board 43, wherein the operation element 431 is from the line
The surface of road plate 43 extends outwardly, and is arranged on the wiring board 43, to ensure more mesh camera main-bodies 40 with normal
Work status.
When more mesh camera main-bodies 40 at work, the operation element 431 generate heat.At this point, 2 quilt of the radiator structure
More mesh camera main-bodies 40 are set to, the heat dissipation bottom surface 211 contacts the operation element 431, to complete the work member
The heat exchange of part 431 and the heat dissipation element 20.
Specifically, when the radiator structure 2 is arranged on more mesh camera main-bodies 40, the heat dissipation bottom surface
The 211 contact operation elements 431, in other words, the operation element 431 is as heat dissipation element 20 described in supporter supports.Institute
It states heat dissipation element 20 to be prepared by the Heat Conduction Material 210, compares the operation element 431 under the condition of high temperature, it is described to dissipate
Thermal element 20 is in low-temperature condition, and the temperature of the operation element 431 is described at this time to dissipate by heat transfer to the heat dissipation element 20
The temperature of thermal element 20 increases, and the air-cooled element 30 and outer end air-flow reduce the heat dissipation member in time by air-cooled technology
The temperature of part 20, so that the heat dissipation element 20 can continue to complete heat exchange with more mesh camera main-bodies 40, with this side
Formula improves the radiating efficiency of more mesh camera main-bodies 40.
In addition, in another embodiment of the utility model, the heat dissipation bottom surface 211 of the heat dissipation element 20 can not
Fully fully contact the operation element 431, such as when the heat dissipation bottom surface 211 is designed to out-of-flatness the case where, or
Person is not such as when the operation element 431 is evenly arranged in the wiring board 43, when the heat dissipation element 20 is set
When more mesh camera main-bodies 40, the heat dissipation bottom surface 211 completely can not fully be bonded the operation element 431,
In this case, the contact area of the heat dissipation element 20 and the operation element 431 in other words heat exchange area by substantially
Degree ground is reduced, and the radiating efficiency of more mesh camera main-bodies 40 is lowered.
In order to solve problem above, in an embodiment of the utility model, at least a heat-conducting medium 50 is arranged at institute
It states between heat dissipation element 20 and the operation element 431, with heat dissipation element described in heat conduction 20 and the operation element 431.Specifically
For, the heat-conducting medium 50 is set to the gap formed between the heat dissipation element 20 and the operation element 431, wherein institute
It states heat-conducting medium 50 and gap between the heat dissipation element 20 and the operation element 431 can be filled, reduce between interface each other
Thermal contact resistance improves the heat transfer between interface each other.
It is noted that the thermal conductivity of the heat-conducting medium 50 is implemented as the thermal conductivity more than air dielectric, to
So that the heat of the operation element 431 can preferably be conducted to the heat dissipation element 20 by the heat-conducting medium 50, from
Even and if to lead to if the heat of 20 operation element 431 of heat dissipation element described in 431 incomplete contact between of the operation element
It crosses the heat-conducting medium 50 and arrives at the heat dissipation element 20.
Certainly, in some embodiments of the utility model, even if the heat dissipation element 20 is entirely set to the work
Make element 431, the heat-conducting medium 50 may also set up between the operation element 431 and the heat dissipation element 20, to improve
The radiating efficiency of more mesh camera main-bodies 40.In an embodiment of the utility model, the heat-conducting medium 50 partly or
It is fully filled between the heat dissipation element 20 and the wiring board 43.
It is noted that the heat of of the wiring board 431 itself can also be conducted to the heat dissipation element 20, speech is changed
It, the heat that more mesh camera main-bodies 40 generate at work can be not only conducted to by the operation element 431
The heat dissipation element 20 also can be conducted to the heat dissipation element 20 by air dielectric or the heat-conducting medium 50, to
Improve the radiating efficiency of more mesh camera main-bodies 40.
In addition, the radiator structure 2 can be arranged at more mesh camera main-bodies 40, such as the heat dissipation in a variety of forms
Structure 2 can realize unicom by a bonding element, a tightening member or other connecting elements with the wiring board 43.It is worth
One is mentioned that, when the heat dissipation bottom surface 211 of the heat dissipation element 20 is contacted with the operation element 431, the heat dissipation knot
Structure 2 does not influence not damaging the normal work of the operation element 431 yet.
Certainly, in order to protect the radiator structure 2 and more mesh camera main-bodies 40, the more mesh cameras of high-cooling property
1 further comprises the protective cover 10, and the protective cover 10 defines a protection chamber 100, wherein the radiator structure 2 and described
More mesh camera main-bodies 40 are housed inside in the protection chamber 100 and are protected.
In the embodiments of the present invention, the radiator structure 2 is assembled in the top side of more mesh camera main-bodies 40,
The radiator structure 2 and more mesh camera main-bodies 40 are stored in the protection chamber 100, to avoid external environment pair
The loss of the radiator structure 2 and more mesh camera main-bodies 40 also can guarantee the radiator structure 2 and more mesh cameras
The structural stability of main body 40.
Specifically, the protection chamber 100 further defines a heat dissipation chamber 101 and a camera chamber 102, wherein described
Heat dissipation chamber 101 is applied to place the radiator structure 2, and the camera chamber 102 is applied to place more mesh camera main-bodies
40, it is worth mentioning at this point that, in order to enable the radiator structure 2 and more mesh camera main-bodies 40 are preferably placed in the protection
It is protected in chamber 100, the protective cover 10 is designed to special shape, to be adapted to the radiator structure 2 and more mesh phases
Owner's body 40.
Specifically, in order to not influence the normal work of more mesh camera main-bodies 40, the protective cover 10 is arranged at least
One camera aperture 11, shape and the position of the camera aperture 11 adapt to the camera lens 42, i.e., when more 40 quilts of mesh camera main-body
When being set to the camera chamber 102, the camera lens 42 corresponds to the camera aperture 11, so that the camera lens 42 can obtain the external world
The data of environment.
In addition, the quantity of the camera aperture 11 adapts to the quantity of the camera lens 42, so that more mesh phase owners
Each camera lens 42 of body 40 can all correspond to an at least camera aperture 11, when more mesh camera main-bodies 40 are placed in the camera
When room 102, ambient can arrive at the camera lens 42 by the camera aperture 11, and then complete the imaging of the camera lens 42.
In addition, in order to not influence the normal work of the radiator structure 2, an at least tuyere notch is arranged in the protective cover 10
12, the tuyere notch 12 corresponds to the air port of the heat dissipation element 20.Specifically, the tuyere notch 12 further comprise to
A few outlet air oral pore 122, wherein when the heat dissipation element 20 is arranged at the heat dissipation chamber 101, the outlet air oral pore 122 is right
The air outlet 232 is answered, so that the air duct 300 of the heat dissipation element 20 can be with extraneous unicom.
In other words, when being protected in the protection chamber 100 that the radiator structure 2 is placed in the protective cover 10, institute
The air outlet 232 for stating heat dissipation element 20 corresponds to the outlet air oral pore 122, and outer end air-flow enters the heat dissipation element 20, and
From the air outlet 232 of the heat dissipation element 20 to external diffusion.The flowing of outer end air-flow can reduce the heat dissipation element 20
Temperature, specifically, the heat exchange of the heat dissipation element 20 and external environment is driven by the flowing of the outer end air-flow, to carry
The thermal diffusivity of the more mesh cameras of the high high-cooling property 1.
In addition, the heat dissipation chamber 101 is adapted to the shape of the radiator structure 2, so that when the radiator structure 2 is placed in
When the heat dissipation chamber 101, the outer surface of the radiator structure 2 is bonded the inner surface of the protective cover 10, prevents hot-air from flowing backwards
The phenomenon that occur.
When the heat dissipation groove 22 is arranged in the radiator structure 2, correspondingly, the outer surface of the protective cover 10 is arranged
An at least recess hole 13, wherein the recess hole 13 corresponds to the heat dissipation groove 22, so that the heat dissipation groove 22 can
Heat exchange occurs with external environment.It is noted that the shape of the recess hole 13, size and quantity Matching are dissipated in described
Hot groove 22.
In addition, it is noted that in an embodiment of the utility model, the protective cover 10 is by a plastic material 14
It is prepared.Unlike traditional technology, the heat of more mesh camera main-bodies 40 is radiated by the radiator structure 2,
So that the protective cover 10 need not bear excessively high temperature, therefore the protective cover 10 can be implemented as by the plastics material
Matter 14 is prepared.
When the protective cover 10 is prepared by the plastic material 14, it can effectively alleviate human body tactile as much as possible
On reaction to hot phenomenon.Specifically, the case where protective cover 10 is prepared by metal material is compared, as the guarantor
When shield 10 is prepared by the plastic material 14, the temperature of of the protective cover 10 itself can avoid the phenomenon for occurring excessively high,
To facilitate taking for user, to improve the user experience of the more mesh cameras of the high-cooling property 1.
In conclusion the camera aperture 11, the tuyere notch 12 and institute is arranged in the protective cover 10 according to actual needs
Recess hole 13 is stated, wherein the shape of the camera aperture 11, the tuyere notch 12 and the groove blank cell 13, quantity and big
It is small to change according to the Change of types of more mesh camera main-bodies 40 and the radiator structure 2.So that the protective cover
10 can not only protect the radiator structure 2 and more mesh camera main-bodies 40, at the same do not influence the radiator structure 2 and
The normal work of more mesh camera main-bodies 40.
In addition, the protective cover 10 is close to the radiator structure 2 and more mesh camera main-bodies 40, can not only ensure
The structural stability of the radiator structure 2 and more mesh camera main-bodies 40, and also ensure that the radiator structure 2 will not
There is a phenomenon where hot air reflows, while reducing the volume of the more mesh cameras of the high-cooling property 1 as much as possible.
In addition, since the volume of the more mesh cameras of the high-cooling property 1 becomes smaller, while thermal diffusivity is good, so that the height
The more mesh cameras of thermal diffusivity 1 can be applied in many fields.For example, the more mesh cameras of the high-cooling property 1 can unicom at least one
Built-in end formula, in the embodiments of the present invention, the built-in end formula is implemented as a mobile phone terminal, by this method, expands institute
State the application field of the more mesh cameras of high-cooling property 1.
In addition, it should be understood by those skilled in the art that the embodiments of the present invention shown in foregoing description and attached drawing
It is only used as illustrating and being not intended to limit the utility model.The purpose of this utility model completely and effectively realizes.This practicality is new
The function and structural principle of type ought show and illustrate in embodiment, under without departing from the principle, the utility model
Embodiment can have any deformation or modification.
Claims (37)
1. a radiator structure is applied to the mesh camera main-body at least more than one that radiates, wherein more mesh camera main-bodies include at least
One wiring board, at least an operation element are arranged at the wiring board, which is characterized in that including:
An at least heat dissipation element, wherein the heat dissipation element is equipped with an at least air outlet, wherein the air outlet be set to it is described
The top side of heat dissipation element, and the air outlet forms an air duct inside the heat dissipation element;And
At least one air-cooled element reduces the heat dissipation member wherein the air-cooled element is set to the air duct in the form of blowing
The temperature of part, the heat dissipation element are set to more mesh camera main-bodies, and heat exchange occurs with more mesh camera main-bodies.
2. radiator structure according to claim 1, wherein the heat dissipation element includes an at least heat sink body, described to dissipate
Hot body contact operation element, heat exchange occurs with the operation element.
3. radiator structure according to claim 2, wherein at least one is arranged between the heat sink body and the wiring board and leads
Thermal medium, wherein the heat-conducting medium thermal conductivity leads to the heat sink body and the operation element.
4. radiator structure according to claim 2 or 3, wherein at least one heat dissipation of side surface setting of the heat dissipation element
Groove, wherein the heat dissipation groove increases the surface area of the heat dissipation element.
5. radiator structure according to claim 4, wherein the heat dissipation groove is implemented as a series of radiation tooths, described
Radiation tooth is recessed inwardly in the side surface of the heat sink body.
6. radiator structure according to claim 2, wherein the heat dissipation element is internally provided at least one air-cooled chamber, wherein
The air-cooled element is set to the air-cooled chamber, is handed over wherein by the air outlet and external environment heat occurs for the air-cooled chamber
It changes.
7. radiator structure according to claim 3, wherein the heat dissipation element is internally provided at least one air-cooled chamber, wherein
The air-cooled element is set to the air-cooled chamber, is handed over wherein by the air outlet and external environment heat occurs for the air-cooled chamber
It changes.
8. radiator structure according to claim 6, wherein the accommodating volume of the air-cooled chamber is not less than the air-cooled element
Volume.
9. radiator structure according to claim 7, wherein the accommodating volume of the air-cooled chamber is not less than the air-cooled element
Volume.
10. radiator structure according to claim 4, wherein the heat dissipation element is internally provided at least one air-cooled chamber, wherein
By the air outlet and external environment heat exchange occurs for the air-cooled chamber, wherein the air-cooled element be set to it is described air-cooled
Chamber, wherein the accommodating volume of the air-cooled chamber is not less than the volume of the air-cooled element.
11. radiator structure according to claim 6, wherein the air-cooled element is detachable by an at least tightening member
Ground is fixed on the air-cooled chamber.
12. radiator structure according to claim 7, wherein the air-cooled element is detachable by an at least tightening member
Ground is fixed on the air-cooled chamber.
13. radiator structure according to claim 8, wherein the air-cooled element is detachable by an at least tightening member
Ground is fixed on the air-cooled chamber.
14. radiator structure according to claim 9, wherein the air-cooled element is detachable by an at least tightening member
Ground is fixed on the air-cooled chamber.
15. radiator structure according to claim 7, wherein the thermal conductivity of the heat-conducting medium is more than leading for air dielectric
Heating rate.
16. radiator structure according to claim 12, wherein the thermal conductivity of the heat-conducting medium is more than leading for air dielectric
Heating rate.
17. according to any radiator structure in claim 8 to 16, wherein the heat dissipation element is by a Heat Conduction Material system
It is standby to form.
18. according to any radiator structure in claim 8 to 16, wherein the air-cooled element is implemented as a fan.
19. the more mesh cameras of a high-cooling property, which is characterized in that including:
Mesh camera main-body at least more than one, wherein more mesh camera main-bodies include an at least wiring board, at least two camera lenses, wherein institute
It states camera lens and supports that at least an operation element is set to the wiring board by wiring board work;And an at least radiator structure,
The wherein described radiator structure is set to more mesh camera main-bodies, and heat exchange occurs with more mesh camera main-bodies;
The wherein described radiator structure includes an at least heat dissipation element and at least one air-cooled element, wherein the heat dissipation element is equipped with
An at least air outlet, wherein the air outlet is set to the top side of the heat dissipation element, and the air outlet is in the heat dissipation
An air duct is formed inside element;The wherein described air-cooled element is set to the air duct, and the heat dissipation member is reduced in the form of blowing
The temperature of part.
20. the more mesh cameras of high-cooling property according to claim 19 are led wherein the heat dissipation element includes at least one heat dissipation
Body, the heat sink body contact the operation element, heat exchange occurs with the operation element.
21. the more mesh cameras of high-cooling property according to claim 20, wherein set between the heat sink body and the wiring board
An at least heat-conducting medium is set, wherein the heat-conducting medium thermal conductivity leads to the heat sink body and the operation element.
22. the more mesh cameras of high-cooling property according to claim 20, wherein the side surface setting of the heat dissipation element is at least
One heat dissipation groove, wherein the heat dissipation groove increases the surface area of the heat dissipation element.
23. the more mesh cameras of high-cooling property according to claim 21, wherein the side surface setting of the heat dissipation element is at least
One heat dissipation groove, wherein the heat dissipation groove increases the surface area of the heat dissipation element.
24. the more mesh cameras of high-cooling property according to claim 20, wherein the heat dissipation element is internally provided with an at least wind
Cold chamber, wherein by the air outlet and external environment heat exchange occurs for the air-cooled chamber, wherein the air-cooled element is set to
The air-cooled chamber.
25. the more mesh cameras of high-cooling property according to claim 21, wherein the heat dissipation element is internally provided with an at least wind
Cold chamber, wherein by the air outlet and external environment heat exchange occurs for the air-cooled chamber, wherein the air-cooled element is set to
The air-cooled chamber.
26. the more mesh cameras of high-cooling property according to claim 23, wherein the heat dissipation element is internally provided with an at least wind
Cold chamber, wherein by the air outlet and external environment heat exchange occurs for the air-cooled chamber, wherein the air-cooled element is set to
The air-cooled chamber.
27. the more mesh cameras of high-cooling property according to claim 25, wherein the more mesh cameras of high-cooling property further wrap
A protective cover is included, wherein the protective cover defines a protection chamber, the radiator structure and more mesh camera main-bodies are set
It is protected in the protection intracavitary.
28. the more mesh cameras of high-cooling property according to claim 26, wherein the more mesh cameras of high-cooling property further wrap
A protective cover is included, wherein the protective cover defines a protection chamber, the radiator structure and more mesh camera main-bodies are set
It is protected in the protection intracavitary.
29. the more mesh cameras of high-cooling property according to claim 27, wherein the protection chamber define an at least heat dissipation chamber with
And an at least camera chamber, wherein the volume of the heat dissipation chamber adapts to the radiator structure, so that when the radiator structure is set
When being placed in the heat dissipation chamber, the outer surface of the radiator structure fits in the inner surface of the heat dissipation chamber.
30. the more mesh cameras of high-cooling property according to claim 28, wherein the protection chamber define an at least heat dissipation chamber with
And an at least camera chamber, wherein the volume of the heat dissipation chamber adapts to the radiator structure, so that when the radiator structure is set
When being placed in the heat dissipation chamber, the outer surface of the radiator structure fits in the inner surface of the heat dissipation chamber.
31. the more mesh cameras of high-cooling property according to claim 27, wherein an at least tuyere notch is arranged in the protective cover,
The shape size and quantity of the wherein described tuyere notch adapt to the air port of the radiator structure.
32. the more mesh cameras of high-cooling property according to claim 28, wherein an at least tuyere notch is arranged in the protective cover,
The shape size and quantity of the wherein described tuyere notch adapt to the air port of the radiator structure.
33. the more mesh cameras of high-cooling property according to claim 27, wherein an at least heat emission hole is arranged in the protective cover,
The shape size and quantity of the wherein described heat emission hole adapt to the heat dissipation groove of the radiator structure.
34. the more mesh cameras of high-cooling property according to claim 28, wherein an at least heat emission hole is arranged in the protective cover,
The shape size and quantity of the wherein described heat emission hole adapt to the heat dissipation groove of the radiator structure.
35. according to any more mesh cameras of high-cooling property in claim 26 to 34, wherein the heat conduction of the heat-conducting medium
Rate is more than the thermal conductivity of air dielectric.
36. according to any more mesh cameras of high-cooling property in claim 26 to 34, wherein the heat dissipation element is led by one
Hot material is prepared.
37. according to any more mesh cameras of high-cooling property in claim 26 to 34, wherein the air-cooled element is carried out
For a fan.
Priority Applications (1)
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CN201820006868.6U CN207764535U (en) | 2018-01-03 | 2018-01-03 | The more mesh cameras of high-cooling property and its radiator structure |
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CN201820006868.6U CN207764535U (en) | 2018-01-03 | 2018-01-03 | The more mesh cameras of high-cooling property and its radiator structure |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN115134503A (en) * | 2022-08-30 | 2022-09-30 | 苏州次源科技服务有限公司 | High-efficient radiating motion image sensor |
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2018
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN115134503A (en) * | 2022-08-30 | 2022-09-30 | 苏州次源科技服务有限公司 | High-efficient radiating motion image sensor |
CN115134503B (en) * | 2022-08-30 | 2022-11-01 | 苏州次源科技服务有限公司 | High-efficient radiating motion image sensor |
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Effective date of registration: 20181126 Address after: 315408 No. 1918 Shinan West Road, Lanjiang Street, Yuyao City, Ningbo City, Zhejiang Province Patentee after: Yuyao sunny Intelligent Optical Technology Co Ltd Address before: 310052 21/F, Block A, Zhihui Center, 1190 Binan Road, Binjiang District, Hangzhou City, Zhejiang Province Patentee before: Zhejiang sunny Intelligent Optical Technology Co Ltd |
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