CN221200104U - High definition FPV glasses suitable for near-sighted - Google Patents

Abstract

The utility model discloses high-definition FPV glasses suitable for myopia, which comprise an FPV glasses body, a transmission module, a functional module, a PCB (printed circuit board) assembly, a magnifier and a defogging fan, wherein a first air channel and a mounting position are respectively arranged at the front end and the rear end of the FPV glasses body, an air port communicated with the mounting position is arranged on the first air channel, and the air port is positioned above the magnifier; the bottom of function module corresponds first wind channel department and is provided with the second wind channel, be provided with the location position in the second wind channel, first wind channel and second wind channel enclose the configuration and form air supply channel, the defogging fan is installed in the location position to make defogging fan's amount of wind blow to the magnifying glass through air supply channel, wind gap in proper order, utilize the magnifying glass to be arranged in amplifying the image in the display screen of function module, in order to solve near-sighted crowd and use FPV glasses to appear unclear problem, and utilize the defogging fan to reach the defogging to the magnifying glass.

Description

High definition FPV glasses suitable for near-sighted

Technical Field

The utility model relates to the technical field of FPV glasses, in particular to high-definition FPV glasses suitable for myopia.

Background

The FPV glasses can return the images of the unmanned aerial vehicle camera in real time, so that the flying hand flies in a first-person-to-principal-view angle like sitting in an aircraft cockpit. The existing FPV glasses need to be connected with a host device through a transmission line, so that transmission of picture audio frequency and signal instructions is achieved, and a user of the FPV glasses is limited by the distance of the transmission line in actual use or interacts with a scene by means of hardware equipment, so that the manufacturing cost is high, and the use experience of the user is affected. In order to improve the viewing effect, the FPV glasses generally adopt a closed structure, so that a myopic user must take down the near vision glasses when using the device, thereby reducing the definition of the myopic user when watching, and further reducing the viewing effect of the myopic user.

The FPV glasses comprise a watch shell, an inner shell and a display, wherein three groups of radiating hole groups are respectively formed on the left side surface and the right side surface of the watch shell, a myopia lens is embedded in the inner shell, two kidney-shaped radiating holes are respectively formed on the left side surface and the right side surface of the inner shell, the two kidney-shaped radiating holes are respectively formed on the inner shell between the adjacent radiating hole groups, and a filter screen is arranged on each kidney-shaped radiating hole; the FPV glasses are compatible with the myopia glasses, the problem that the use of the FPV glasses by a myopic crowd is unclear can be effectively solved, but due to the fact that the FPV glasses are attached to the face, a sealed space environment is formed, when a user uses the FPV glasses for a long time or the user moves violently, the fogging condition of the myopia glasses of the FPV glasses is easy to occur, the actual experience effect of the user is poor, and the kidney-shaped radiating holes cannot radiate fog on the near-vision glasses.

Therefore, a new technical solution is needed to solve the above problems.

Disclosure of utility model

In view of the above, the main objective of the present utility model is to provide a high definition FPV glasses suitable for myopia, which uses an magnifier to amplify the image in the display screen of the functional module through the structural design and cooperation among the FPV glasses body, the functional module, the magnifier and the defogging fan, so as to solve the problem that the use of the FPV glasses by the myopia crowd is unclear, and the defogging of the magnifier is achieved by the defogging fan, so that the problem that the fog on the myopia glasses is difficult to be dispersed through the kidney-shaped heat dissipation holes in the traditional technology is effectively solved.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the high-definition FPV glasses suitable for the myopia comprise an FPV glasses body, a transmission module, a functional module, a PCB (printed circuit board) assembly, a magnifying glass and a defogging fan, wherein the magnifying glass is used for magnifying images in a display screen of the functional module; the defogging fan is used for removing fog on the amplifying mirror surface; the transmission module is electrically connected with the PCB assembly and arranged on the FPV glasses body, and the functional module is electrically connected with the PCB assembly and arranged in the FPV glasses body;

The front end and the rear end of the FPV glasses body are respectively provided with a first air duct and an installation position for installing a magnifying glass, an air port communicated with the installation position is arranged on the first air duct, the magnifying glass is installed in the installation position, and the air port is positioned above the magnifying glass;

The bottom of function module corresponds first wind channel department and is provided with the second wind channel, be provided with the setting position that is used for defogging fan installation location in the second wind channel, first wind channel and second wind channel enclose the configuration and form air supply channel, defogging fan installs in setting position to make defogging fan's amount of wind blow to the magnifying glass through air supply channel, wind gap in proper order.

As a preferable scheme, the functional module comprises an optical structural member, a display screen, a beam splitter and a reflector; the second air duct is arranged at the bottom of the optical structural member, the optical structural member is provided with an inner cavity, the top and the rear side of the inner cavity are respectively provided with a light source input port, and the rear side of the inner cavity is provided with a light source output port; the transmission module is electrically connected with the plurality of receiving modules, the plurality of receiving modules are electrically connected with the PCB assembly, and the PCB assembly is arranged at the top of the optical structural member and is positioned above the light source input port;

The display screen is arranged in the inner cavity and is positioned at the front side of the inner cavity, the light splitting sheet extends downwards from back to front in an inclined mode to be positioned at the light source output port and at the rear side of the display screen, the reflector is arranged corresponding to the light source input port and is positioned at the top of the display screen and the light splitting sheet, and the magnifier is positioned at the rear side of the light source output port.

As a preferable scheme, the transmission module comprises two built-in antennas and two external antennas, wherein the two built-in antennas and the two external antennas are respectively and electrically connected with the receiving module, and the two built-in antennas are arranged on the front side surface of the optical structural member.

As a preferable scheme, the FPV glasses body comprises a glasses upper cover, a glasses lower cover, a glasses front cover and a glasses mask; the upper glasses cover and the lower glasses cover are assembled up and down to wrap the upper side and the lower side of the optical structural part; the glasses face guard is assembled in the rear sides of the glasses upper cover and the glasses lower cover, and the glasses front cover is assembled in the front sides of the glasses upper cover and the glasses lower cover.

As a preferable mode, the rear side of the optical structural member is provided with a first connecting part and a second connecting part; correspondingly, the outer ring side of the glasses front cover is respectively provided with a first annular clamping part and a second annular clamping part, and the outer ring side of the glasses upper cover is respectively provided with a first annular butt joint part and a first annular clamping groove which is used for being matched with the first annular clamping part; the outer ring side of the glasses lower cover is respectively provided with a second annular butt joint part and a second annular clamping groove which is used for being matched with the second annular clamping part; the outer ring side of the glasses mask is respectively provided with a third annular butt joint part and a fourth annular butt joint part which are used for being matched with the first annular butt joint part and the second annular butt joint part, and a first mounting groove and a second mounting groove which are used for being matched with the first annular connecting part and the second annular connecting part; the first annular clamping part and the second annular clamping part are respectively clamped in the first annular clamping groove and the second annular clamping groove, the third annular butt joint part and the second annular butt joint part respectively abut against the first annular butt joint part and the second annular butt joint part, and the first connecting part and the second connecting part are respectively arranged in the first mounting groove and the second mounting groove.

As a preferable scheme, the first air duct is arranged at the front end of the glasses mask, the installation position is positioned at the inner side of the rear end of the glasses mask, and the glasses upper cover, the glasses lower cover, the glasses front cover and the glasses mask are mutually assembled to form a placement cavity in a surrounding shape so as to wrap the functional module in the placement cavity.

As a preferred scheme, PCB board subassembly is fixed in the top of optical structure spare and is located and places the intracavity through the support, optical structure spare's top week side is provided with a plurality of first connecting holes, correspondingly, support's periphery side corresponds a plurality of first connecting holes department and is provided with a plurality of second connecting holes, the support passes first connecting hole and second connecting hole respectively in order to lock in optical structure spare's top through the fastener.

As a preferable scheme, the support is provided with a cooling fan corresponding to the PCB assembly, the glasses upper cover is provided with an air inlet corresponding to the cooling fan, the air inlet is communicated with the placing cavity, the glasses lower cover is provided with an air outlet, and the air outlet is communicated with the placing cavity.

As a preferable scheme, the glasses upper cover is also provided with a control panel, the control panel is provided with a frequency modulation key and a power key, and the frequency modulation key and the power key are connected to the PCB assembly.

As a preferable scheme, the PCB assembly is further provided with a charging port, and the charging port is exposed out of the glasses lower cover.

Compared with the prior art, the utility model has obvious advantages and beneficial effects, in particular, the technical scheme is that the FPV glasses are mainly designed and matched through the structure among the FPV glasses body, the functional module, the magnifier and the demisting fan, the front end and the rear end of the FPV glasses body are respectively provided with a first air duct and a mounting position, the first air duct is provided with an air port communicated with the mounting position, the magnifier is arranged in the mounting position, and the air port is positioned above the magnifier; the utility model provides a function module's bottom corresponds first wind channel department and is provided with the second wind channel, first wind channel and second wind channel enclose the configuration and form air supply channel, the defogging fan is installed in the position of locating to make defogging fan's amount of wind blow to the magnifying glass through air supply channel, wind gap in proper order, utilize the magnifying glass to be arranged in amplifying the image in the display screen of function module, in order to solve near-sighted crowd and use the FPV glasses to appear unclear problem, and utilize the defogging fan to reach the defogging to amplifying the lens, still be the wind channel structure from taking on FPV glasses body and the function module, it need not to increase and outer wind channel structure, thereby can effectually reduce the self weight of FPV glasses.

In order to more clearly illustrate the structural features and efficacy of the present utility model, the present utility model will be described in detail below with reference to the accompanying drawings and examples.

Drawings

FIG. 1 is a perspective view of an embodiment of the present utility model;

FIG. 2 is a cross-sectional view of an embodiment of the present utility model;

FIG. 3 is another cross-sectional view of an embodiment of the present utility model;

FIG. 4 is yet another cross-sectional view of an embodiment of the present utility model;

FIG. 5 is an exploded view of an embodiment of the present utility model;

FIG. 6 is another exploded view of an embodiment of the present utility model.

The attached drawings are used for identifying and describing:

10. FPV glasses body 11, glasses upper cover

12. Lower cover 13 and front cover of glasses

14. Glasses face mask 15 and placing cavity

111. Control panel 112, first annular butt joint portion

113. First annular clamping groove 114 and first air duct

115. Mounting position 116, tuyere

117. Air inlet 121, second annular butt joint

122. Second annular clamping groove 123 and air outlet

131. First annular clamping portion 132 and second annular clamping portion

141. Third annular butt joint 142, fourth annular butt joint

143. First mounting groove 144, second mounting groove

20. Transmission module 21, built-in antenna

22. External antenna 30 and functional module

31. Optical structure 32 and display screen

33. Light splitting sheet 34, reflector

311. First and second connection portions 312 and 312

313. Second air duct 314 and air supply channel

315. Setting bit 316, light source input port

317. Light source outlet 318, lumen

319. First connecting hole 35, bracket

351. Second connecting hole 352 and cooling fan

40. PCB assembly 41, charging port

50. Magnifier 60, defogging fan.

Detailed Description

Referring to fig. 1 to 6, specific structures of embodiments of the present utility model are shown.

In the description of the present utility model, it should be noted that, for the azimuth words, terms such as "upper", "lower", "front", "rear", "left", "right", etc., indicate azimuth and positional relationships as shown based on the drawings or when worn normally, only for convenience of describing the present utility model and simplifying the description, but do not indicate or imply that the device or element to be referred must have a specific azimuth, be configured and operated in a specific azimuth, and should not be construed as limiting the specific protection scope of the present utility model.

The utility model provides a high definition FPV glasses suitable for near-sighted, is including FPV glasses body 10, transmission module 20, function module 30, PCB board subassembly 40, magnifying glass 50 and defogging fan 60.

The magnifying glass 50 is used for magnifying the image in the display screen 32 of the functional module 30; the defogging fan 60 is used for removing fog on the surface of the magnifying glass 50; the transmission module 20 is electrically connected to the PCB assembly 40 and disposed on the FPV glasses body 10, and the functional module 30 is electrically connected to the PCB assembly 40 and disposed in the FPV glasses body 10.

The front end and the rear end of the FPV glasses body 10 are respectively provided with a first air duct 114 and an installation position 115 for installing the magnifier 50, the first air duct 114 is provided with an air port 116 communicated with the installation position 115, the magnifier 50 is installed in the installation position 115, and the air port 116 is positioned above the magnifier 50;

The FPV glasses body 10 comprises a glasses upper cover 11, a glasses lower cover 12, a glasses front cover 13 and a glasses mask 14; the upper and lower glasses covers 11 and 12 are assembled up and down to each other so as to be wrapped on the upper and lower sides of the optical structural member 31; the glasses mask 14 is assembled to the rear sides of the glasses upper cover 11 and the glasses lower cover 12, and the glasses front cover 13 is assembled to the front sides of the glasses upper cover 11 and the glasses lower cover 12.

Preferably, the first air duct 114 is disposed at the front end of the glasses mask 14, the mounting location 115 is located inside the rear end of the glasses mask 14, and the glasses upper cover 11, the glasses lower cover 12, the glasses front cover 13, and the glasses mask 14 are assembled with each other to form the placement cavity 15 in a surrounding manner, so as to wrap the functional module 30 in the placement cavity 15. Preferably, the glasses upper cover 11 is further provided with a control panel 111, and the control panel 111 is provided with a frequency modulation key and a power key, and the frequency modulation key and the power key are connected to the PCB assembly 40.

The rear side of the optical structure member 31 is provided with a first connection portion 311 and a second connection portion 312; correspondingly, the outer ring side of the front cover 13 is provided with a first annular clamping part 131 and a second annular clamping part 132 respectively, and the outer ring side of the upper cover 11 is provided with a first annular butt joint part 112 and a first annular clamping groove 113 adapted to the first annular clamping part 131 respectively; the outer ring side of the lower cover 12 is provided with a second annular butt joint part 121 and a second annular clamping groove 122 adapted to the second annular clamping part 132 respectively; the outer ring side of the glasses mask 14 is provided with a third annular butt joint part 141 and a fourth annular butt joint part 142 which are used for being matched with the first annular butt joint part 112 and the second annular butt joint part 121, and a first mounting groove 143 and a second mounting groove 144 which are used for being matched with the first annular connecting part and the second annular connecting part; the first annular clamping portion 131 and the second annular clamping portion 132 are respectively clamped in the first annular clamping groove 113 and the second annular clamping groove 122, the third annular butt joint portion 141 and the second annular butt joint portion 121 are respectively abutted on the first annular butt joint portion 112 and the second annular butt joint portion 121, and the first connecting portion 311 and the second connecting portion 312 are respectively arranged in the first mounting groove 143 and the second mounting groove 144.

Preferably, the transmission module 20 includes two internal antennas 21 and two external antennas 22, the two internal antennas 21 and the two external antennas 22 are respectively and electrically connected to the receiving module (not shown), and the two internal antennas 21 are mounted on the front side of the optical structural member 31, so as to meet the multi-scenario signal transmission requirement by adopting the combined design of the internal antennas 21 and the external antennas 22.

The bottom of the functional module 30 is provided with a second air duct 313 corresponding to the first air duct 114, a placement position 315 for installing and positioning the demisting fan 60 is provided in the second air duct 313, the first air duct 114 and the second air duct 313 are configured to form an air supply channel 314, and the demisting fan 60 is provided in the placement position 315, so that the air volume of the demisting fan 60 is blown to the magnifier 50 through the air supply channel 314 and the air port in sequence.

The functional module 30 comprises an optical structural member 31, a display screen 32, a light splitting sheet 33 and a reflecting mirror 34; the second air duct 313 is disposed at the bottom of the optical structural member 31, the optical structural member 31 has an inner cavity 318, the top and the rear side of the inner cavity 318 are respectively provided with a light source input port 316, and the rear side is provided with a light source output port 317; the transmission module 20 is electrically connected to a plurality of receiving modules, the plurality of receiving modules are electrically connected to the PCB assembly 40, and the PCB assembly 40 is disposed on top of the optical structural member 31 and above the light source input port 316;

The display screen 32 is disposed in the inner cavity 318 and is located at the front side of the inner cavity 318, the light splitting sheet 33 extends downward from the back to the front to be located at the light source output port 317 and is located at the rear side of the display screen 32, the reflective mirror 34 is disposed corresponding to the light source input port 316 and is located at the top of the display screen 32 and the light splitting sheet 33, and the magnifying glass 50 is located at the rear side of the light source output port 317. The reflector 34 has a rear concave cambered surface as a reflecting surface; the light source irradiates vertically downwards from the light source input port 316 at the top, irradiates to the rear side of the spectroscope and is reflected forward to the reflecting surface of the reflecting mirror 34, and then is reflected backward and is emitted backward from the light source output port 317 through the light splitting sheet 33.

The PCB board assembly 40 is fixedly arranged at the top of the optical structural member 31 and is located in the placement cavity 15 through a bracket 35, a plurality of first connecting holes 319 are formed in the peripheral side of the top of the optical structural member 31, correspondingly, a plurality of second connecting holes 351 are formed in the peripheral side of the bracket 35 corresponding to the plurality of first connecting holes 319, and the bracket 35 respectively penetrates through the first connecting holes 319 and the second connecting holes 351 through locking pieces to be locked at the top of the optical structural member 31. Preferably, the PCB assembly 40 is further provided with a charging port 41, and the charging port 41 is exposed outside the glasses lower cover 12. The optical structural member 31 is further provided with a power supply for supplying power to the defogging fan 60, and the defogging fan 60 is electrically connected to the power supply.

Preferably, a cooling fan 352 is further disposed on the bracket 35 corresponding to the PCB assembly 40, the upper cover 11 of the glasses has an air inlet 117 corresponding to the cooling fan 352, the air inlet 117 is communicated with the placement cavity 15, the lower cover 12 of the glasses is provided with an air outlet 123, and the air outlet 123 is communicated with the placement cavity 15.

The design focus of the utility model is that the FPV glasses are mainly designed and matched through the structure among the FPV glasses body, the functional module, the magnifier and the defogging fan, the front end and the rear end of the FPV glasses body are respectively provided with a first air duct and a mounting position, the first air duct is provided with an air port communicated with the mounting position, the magnifier is arranged in the mounting position, and the air port is positioned above the magnifier; the utility model provides a function module's bottom corresponds first wind channel department and is provided with the second wind channel, first wind channel and second wind channel enclose the configuration and form air supply channel, the defogging fan is installed in the position of locating to make defogging fan's amount of wind blow to the magnifying glass through air supply channel, wind gap in proper order, utilize the magnifying glass to be arranged in amplifying the image in the display screen of function module, in order to solve near-sighted crowd and use the FPV glasses to appear unclear problem, and utilize the defogging fan to reach the defogging to amplifying the lens, still be the wind channel structure from taking on FPV glasses body and the function module, it need not to increase and outer wind channel structure, thereby can effectually reduce the self weight of FPV glasses.

The foregoing description is only a preferred embodiment of the present utility model, and is not intended to limit the technical scope of the present utility model, so any minor modifications, equivalent changes and modifications made to the above embodiments according to the technical principles of the present utility model are still within the scope of the technical solutions of the present utility model.

Claims (10)

1. High definition FPV glasses suitable for near-sighted, its characterized in that: the pair of FPV glasses comprises an FPV glasses body, a transmission module, a functional module, a PCB assembly, a magnifying glass and a defogging fan, wherein the magnifying glass is used for magnifying images in a display screen of the functional module; the defogging fan is used for removing fog on the amplifying mirror surface; the transmission module is electrically connected with the PCB assembly and arranged on the FPV glasses body, and the functional module is electrically connected with the PCB assembly and arranged in the FPV glasses body;

The front end and the rear end of the FPV glasses body are respectively provided with a first air duct and an installation position for installing a magnifying glass, an air port communicated with the installation position is arranged on the first air duct, the magnifying glass is installed in the installation position, and the air port is positioned above the magnifying glass;

The bottom of function module corresponds first wind channel department and is provided with the second wind channel, be provided with the setting position that is used for defogging fan installation location in the second wind channel, first wind channel and second wind channel enclose the configuration and form air supply channel, defogging fan installs in setting position to make defogging fan's amount of wind blow to the magnifying glass through air supply channel, wind gap in proper order.

2. The high definition FPV glasses for myopia according to claim 1, wherein: the functional module comprises an optical structural member, a display screen, a beam splitter and a reflector; the second air duct is arranged at the bottom of the optical structural member, the optical structural member is provided with an inner cavity, the top and the rear side of the inner cavity are respectively provided with a light source input port, and the rear side of the inner cavity is provided with a light source output port; the transmission module is electrically connected with the plurality of receiving modules, the plurality of receiving modules are electrically connected with the PCB assembly, and the PCB assembly is arranged at the top of the optical structural member and is positioned above the light source input port;

The display screen is arranged in the inner cavity and is positioned at the front side of the inner cavity, the light splitting sheet extends downwards from back to front in an inclined mode to be positioned at the light source output port and at the rear side of the display screen, the reflector is arranged corresponding to the light source input port and is positioned at the top of the display screen and the light splitting sheet, and the magnifier is positioned at the rear side of the light source output port.

3. The high definition FPV glasses for myopia according to claim 1, wherein: the transmission module comprises two built-in antennas and two external antennas, wherein the two built-in antennas and the two external antennas are respectively and electrically connected to the receiving module, and the two built-in antennas are arranged on the front side surface of the optical structural member.

4. The high definition FPV glasses for myopia according to claim 1, wherein: the FPV glasses body comprises a glasses upper cover, a glasses lower cover, a glasses front cover and a glasses mask; the upper glasses cover and the lower glasses cover are assembled up and down to wrap the upper side and the lower side of the optical structural part; the glasses face guard is assembled in the rear sides of the glasses upper cover and the glasses lower cover, and the glasses front cover is assembled in the front sides of the glasses upper cover and the glasses lower cover.

5. The high definition FPV glasses for myopia according to claim 4, wherein: the rear side of the optical structural member is provided with a first connecting part and a second connecting part; correspondingly, the outer ring side of the glasses front cover is respectively provided with a first annular clamping part and a second annular clamping part, and the outer ring side of the glasses upper cover is respectively provided with a first annular butt joint part and a first annular clamping groove which is used for being matched with the first annular clamping part; the outer ring side of the glasses lower cover is respectively provided with a second annular butt joint part and a second annular clamping groove which is used for being matched with the second annular clamping part; the outer ring side of the glasses mask is respectively provided with a third annular butt joint part and a fourth annular butt joint part which are used for being matched with the first annular butt joint part and the second annular butt joint part, and a first mounting groove and a second mounting groove which are used for being matched with the first annular connecting part and the second annular connecting part; the first annular clamping part and the second annular clamping part are respectively clamped in the first annular clamping groove and the second annular clamping groove, the third annular butt joint part and the second annular butt joint part respectively abut against the first annular butt joint part and the second annular butt joint part, and the first connecting part and the second connecting part are respectively arranged in the first mounting groove and the second mounting groove.

6. The high definition FPV glasses for myopia according to claim 4, wherein: the first air duct is arranged at the front end of the glasses mask, the installation position is located at the inner side of the rear end of the glasses mask, and the glasses upper cover, the glasses lower cover, the glasses front cover and the glasses mask are mutually assembled to form a placement cavity in a surrounding shape so as to wrap the functional module in the placement cavity.

7. The high definition FPV glasses for myopia according to claim 6, wherein: the PCB assembly is fixedly arranged at the top of the optical structural member and is positioned in the placement cavity through the support, a plurality of first connecting holes are formed in the peripheral side of the top of the optical structural member, correspondingly, a plurality of second connecting holes are formed in the peripheral side of the support, corresponding to the plurality of first connecting holes, and the support penetrates through the first connecting holes and the second connecting holes through the locking piece respectively to be locked at the top of the optical structural member.

8. The high definition FPV glasses for myopia according to claim 7, wherein: the support is provided with a cooling fan corresponding to the PCB assembly, the glasses upper cover is provided with an air inlet corresponding to the cooling fan, the air inlet is communicated with the placing cavity, the glasses lower cover is provided with an air outlet, and the air outlet is communicated with the placing cavity.

9. The high definition FPV glasses for myopia according to claim 4, wherein: the glasses upper cover is also provided with a control panel, the control panel is provided with a frequency modulation key and a power key, and the frequency modulation key and the power key are connected to the PCB assembly.

10. The high definition FPV glasses for myopia according to claim 4, wherein: and the PCB assembly is also provided with a charging port, and the charging port is exposed out of the lower cover of the glasses.