CN215867358U - Glasses - Google Patents

Abstract

The application discloses a pair of glasses. The specific implementation scheme is as follows: the method comprises the following steps: an optical element having an outwardly facing first surface and an inwardly facing second surface; the frame body comprises a first wall facing the same direction as the first surface and a second wall facing the same direction as the second surface, and the optical element is fixedly connected with the frame body; the nose support is connected to the second wall; the air supply chambers are arranged in the frame and are respectively communicated with at least two of the plurality of holes formed in the first wall, the plurality of holes formed in the second wall and the plurality of holes formed in the nose support; and the gas pump is arranged in the frame, the inlet of the gas pump is communicated with the opening on the frame, and the outlet of the gas pump is respectively communicated with the at least two gas supply chambers so as to respectively adjust the gas parameters of the at least two gas supply chambers.

Description

Glasses

Technical Field

The present disclosure relates to the field of glasses technology, in particular to glasses.

Background

The glasses are in various types, such as common myopia glasses, distance vision glasses, AR (augmented reality) glasses and the like. Wherein, the myopia glasses and the distance glasses are used for enabling people to clearly identify the seen objects. The AR glasses can provide entertainment functions for consumers, such as watching movies, television shows, playing games, etc., and also can provide comfortable online shopping functions, and also provide office comfort, travel virtualization, etc., which are not always the same but many. Each type of glasses has different corresponding effects.

SUMMERY OF THE UTILITY MODEL

The present disclosure provides an eyeglass, comprising: an optical element having an outwardly facing first surface and an inwardly facing second surface; the frame body comprises a first wall facing the same direction as the first surface and a second wall facing the same direction as the second surface, and the optical element is fixedly connected with the frame body; a nose pad attached to the second wall; the air supply chambers are arranged in the frame and are respectively communicated with at least two of the plurality of holes formed in the first wall, the plurality of holes formed in the second wall and the plurality of holes formed in the nose support; and the gas pump is arranged in the frame, the inlet of the gas pump is communicated with the opening on the frame, and the outlet of the gas pump is respectively communicated with the at least two gas supply chambers so as to respectively adjust the gas parameters of the at least two gas supply chambers.

Drawings

FIG. 1 is a schematic diagram of a structure of eyewear provided in accordance with an embodiment of the present disclosure showing a second wall;

FIG. 2 is a schematic diagram of a structure of eyewear provided in accordance with an embodiment of the present disclosure showing a first wall;

fig. 3 is a schematic structural view of an internal arrangement of a frame of an embodiment of the glasses provided by the embodiments of the present disclosure;

fig. 4 is a schematic structural view of an internal arrangement of a frame of another embodiment of the glasses provided by the embodiments of the present disclosure;

fig. 5 is a schematic structural view of the interior of the drying chamber and the temperature adjusting chamber in fig. 3.

The reference numerals in fig. 1-5 are as follows:

1 optical element, 2 first surface, 3 second surface, 4 frame, 5 first wall, 6 second wall, 7 nose pad, 8 holes, 9 gas pump, 10 temperature adjusting chamber, 11 first temperature adjusting chamber, 12 second temperature adjusting chamber, 13 third temperature adjusting chamber, 14 fourth temperature adjusting chamber, 15 fifth temperature adjusting chamber, 16 drying chamber, 17 first drying chamber, 18 second drying chamber, 19 third drying chamber, 20 fourth drying chamber, 21 fifth drying chamber, 22 first gas supply chamber, 23 second gas supply chamber, 24 third gas supply chamber, 25 fourth gas supply chamber, 26 fifth gas supply chamber, 27 control unit, 28 first switch, 29 second switch, 30 third switch, 31 fourth switch, 32 fifth switch, 33 first temperature sensor, 34 second temperature sensor, 35 first humidity sensor, 36 second humidity sensor, 37 hose, 38 third temperature sensor, 39 third humidity sensor, 40 fourth temperature sensor, 41 fourth humidity sensor.

Detailed Description

The following detailed description is to be read with reference to the drawings.

As shown in fig. 1-5, the present disclosure provides eyewear comprising an optical element 1, a frame 4, a nosepiece 7, a gas pump 9, and at least two gas supply chambers.

The optical element 1 has a first surface 2 facing outwards and a second surface 3 facing inwards. The optical element 1 may be a lens of a myopic lens, or a lens of AR glasses, which is provided according to the specific class of glasses. When the glasses are worn, the direction from the optical element 1 to the wearer is an inward direction, the direction from the optical element 1 to the opposite direction from the wearer is an outward direction, the first surface 2 of the optical element 1 is arranged outwards, and the second surface 3 of the optical element 1 is arranged inwards.

The frame 4 comprises a first wall 5 facing the same as the first surface 2 and a second wall 6 facing the same as the second surface 3. The optical element 1 is fixedly connected to a frame 4, and the frame 4 is used for supporting and fixing the optical element 1. For example, a side wall is connected between the first wall 5 and the second wall 6, the first wall 5, the second wall 6 and the side wall form the frame 4, and the optical element 1 is fixedly connected to the side wall.

A nose pad 7 may be attached to the second wall 6. The nose pads 7 are used to bridge the eyeglasses over the bridge of the wearer's nose.

At least two air supply chambers are separated from each other, and both of the at least two air supply chambers are provided in the frame body 4. At least two air supply chambers are respectively communicated with at least two of the plurality of holes 8 formed on the first wall 5, the plurality of holes 8 formed on the second wall 6 and the plurality of holes 8 formed on the nose support 7. Wherein, a plurality of holes 8 are opened on the first wall 5, the gas provided by the gas supply chamber communicated with the first wall can be output through the plurality of holes 8, similarly, a plurality of holes 8 are opened on the second wall 6 and the nose support 7 respectively, and the gas provided by the gas supply chamber communicated with the second wall can be output through the plurality of holes 8. The number of the air supply chambers is at least two, the air supply chambers are arranged in a mutually separated mode, the separated air supply chambers are respectively communicated with at least two of the plurality of holes 8 formed in the first wall 5, the plurality of holes 8 formed in the second wall 6 and the plurality of holes 8 formed in the nose support 7, and air provided by each air supply chamber can be output to the corresponding holes 8 communicated with the air supply chambers. The at least two air supply chambers communicate with at least two of the first wall 5, the second wall 6 and the holes in the nosepiece 7 in a more frequent manner, as will be explained in more detail later.

And a gas pump 9 provided in the housing 4, wherein an inlet of the gas pump 9 communicates with an opening in the housing 4, so that gas enters the gas pump 9 from the outside of the housing 4 through the opening. The outlet of the gas pump 9 is connected to at least two gas supply chambers, and gas can be supplied to each of the gas supply chambers which are separated from each other. For example, the gas output from different outlets of the gas pump 9 can enter different gas supply chambers, the gas parameters output from different outlets of the gas pump 9 can be different, and the gas parameters of the gas output from the plurality of holes 8 in the first wall 5 or the plurality of holes 8 in the second wall 6 or the plurality of holes 8 in the nose pad 7 which are communicated with the gas supply chambers can be respectively adjusted. For another example, an outlet of the gas pump 9 may pump gas, the gas output from the gas pump 9 may be adjusted separately, and the gas parameters of the gas entering different gas supply chambers may be different, so that the gas parameters of the gas output from the plurality of holes 8 on the first wall 5, the plurality of holes 8 on the second wall 6, or the plurality of holes 8 on the nose pad 7, which are communicated with the gas supply chambers, may be adjusted separately. The gas supply chambers are spaced apart from each other to enable independence of gas parameters of the gas entering each gas supply chamber, which may be temperature of the gas, humidity of the gas, etc. For example, the holes 8 formed in the first wall 5 communicate with an air supply chamber, and when the holes 8 formed in the first wall 5 are required to output air of a specific temperature and humidity, the gas parameters of the air in the air supply chamber communicated with the holes can be adjusted to reach the specific temperature and humidity.

In some embodiments, the category of the glasses is AR glasses. The AR glasses include a lens, a frame 4, a nose pad 7, three gas supply chambers, and a gas pump 9.

The lens for AR glasses has a first surface 2 facing outwards and a second surface 3 facing inwards. The outwardly facing first surface 2 is for receiving ambient light. The inwardly facing second surface 3 serves to exit the image light and the ambient light on the display of the AR glasses into the eyes of the user wearing the AR glasses so that the user may experience the effect of augmented reality.

The frame 4 comprises a first wall 5 facing the same as the first surface 2 and a second wall 6 facing the same as the second surface 3. The lens is fixedly connected with the frame body 4. The number of the lenses is two, which are arranged on the left and the right, and the lenses are respectively fixedly connected in the left part and the right part of the frame body 4. The left and right portions of the frame 4 refer to a frame portion facing the left eye of the user and a frame portion facing the right eye of the user when the user wears the AR glasses.

The nose pads 7 are attached to the second inwardly directed wall 6. For example, the nose pads 7 may be removably attached to the second wall 6.

The three air supply chambers are separated from each other, and are a first air supply chamber 22, a second air supply chamber 23, and a third air supply chamber 24, respectively. The first air supply chamber 22 communicates with the plurality of holes 8 formed in the first wall 5, the second air supply chamber 23 communicates with the plurality of holes 8 formed in the second wall 6, and the third air supply chamber 24 communicates with the plurality of holes 8 formed in the nose piece 7. When the communication is specifically performed, the following modes can be adopted: the outlets of the first air supply chamber 22 are respectively communicated with the plurality of holes 8 formed in the first wall 5 in a one-to-one correspondence manner through a plurality of hoses (not shown), the outlets of the second air supply chamber 23 are respectively communicated with the plurality of holes 8 formed in the second wall 6 in a one-to-one correspondence manner through a plurality of hoses (not shown), and the outlets of the third air supply chamber 24 are respectively communicated with the plurality of holes 8 formed in the nose support 7 in a one-to-one correspondence manner through a plurality of hoses (not shown).

And a gas pump 9 provided in the housing 4. The frame 4 is provided with an opening, and an inlet of the gas pump 9 is communicated with the opening. For example, the inlet of the gas pump 9 communicates with a hose to the opening of the frame 4 so that the gas pump 9 can pump in ambient air from the opening. The gas pump 9 may be provided with three different outlet branches, which communicate with the first gas supply chamber 22, the second gas supply chamber 23 and the third gas supply chamber 24, respectively, via hoses 37.

When the air supply chamber communicates with the plurality of holes 8, the following manner is also possible: the first air supply chamber 22 is formed in the housing 4 at a position close to the outside, and the first wall 5 is formed as a side wall of the first air supply chamber 22, which corresponds to a plurality of holes 8 opened in the side wall (i.e., the first wall 5) directly above the first air supply chamber 22. The second air supply chamber 23 is formed in the housing 4 at a position close to the inside, and the second wall 6 is formed as a side wall of the second air supply chamber 23, which corresponds to opening the plurality of holes 8 directly in the side wall (i.e., the second wall 6) of the second air supply chamber 23. The nose pad 7 has a space therein to form a third air supply chamber 24, and a plurality of holes may be directly opened in the wall of the nose pad 7. Each gas supply chamber is provided with an inlet which is respectively communicated with the outlet of the gas pump 9 through a hose.

In this embodiment, the gas pump 9 supplies power to the first gas supply chamber 22, and the first gas supply chamber 22 supplies gas to the plurality of holes 8 in the first wall 5 and outputs the gas. The gas pump 9 can also supply gas into the second gas supply chamber 23, and the second gas supply chamber 23 can deliver the gas to the plurality of holes 8 in the second wall 6 and output it. The gas pump 9 can supply gas into the third gas supply chamber 24, and the third gas supply chamber 24 can supply the gas to the plurality of holes 8 in the nose pad 7 and output the gas. The three gas supply chambers, which are separated from each other, are capable of supplying gas, respectively, without interfering with each other, so that the gas supplied to the plurality of holes 8 in the first wall 5, the gas supplied to the plurality of holes in the second wall 6, and the gas supplied to the plurality of holes in the nose pad 7 can be independent of each other without interfering with each other.

For example, the first gas supply chamber 22 may be supplied with gas by a gas pump 9, and the first gas supply chamber 22 may discharge the gas through a plurality of holes 8 in the first wall 5. Alternatively, the gas may be supplied to the second gas supply chamber 23 by the gas pump 9, and the second gas supply chamber 23 may discharge the gas through the plurality of holes 8 in the second wall 6. Alternatively, the third gas supply chamber 24 may be supplied with gas by the gas pump 9, and the third gas supply chamber 24 may discharge the gas through the plurality of holes 8 of the nosepiece 7. Obviously, the air supply of the three passages can be performed synchronously, or the air supply of two passages or the air supply of one passage can be selected according to specific working conditions. Under any working condition, the air supply of the three passages is independent and does not interfere with each other.

In some embodiments, the number of gas supply chambers is two. The two air supply chambers are a fourth air supply chamber 25 and a fifth air supply chamber 26, respectively. As shown in fig. 4, the fourth air supply chamber 25 communicates with the plurality of holes 8 of the first wall 5 to supply air to the plurality of holes 8, and the fifth air supply chamber 26 communicates with the plurality of holes 8 of the second wall 6 to supply air to the plurality of holes 8. Since the gas exiting the plurality of holes 8 in the first wall 5 and the gas exiting the plurality of holes 8 in the second wall 6 are independent of each other, it is possible to circulate the gas parameters, such as the gas temperature and/or humidity, which are respectively required. The two air supply chambers communicate with a plurality of holes 8 in the first wall 5 and a plurality of holes 8 in the second wall 6, respectively. In some embodiments, the two air supply chambers may also be in communication with a plurality of holes 8 in the first wall 5 and a plurality of holes 8 in the nose piece 7, respectively. In some embodiments, the two air supply chambers may also be in communication with the plurality of holes 8 in the second wall 6 and the plurality of holes 8 in the nosepiece 7, respectively. In some embodiments, the fourth supply chamber 25 communicates with the plurality of holes 8 in the first wall 5 and the plurality of holes 8 in the nosepiece 7, and the fifth supply chamber 26 communicates with the plurality of holes 8 in the second wall 6. At this time, the plurality of holes 8 of the first wall 5 and the plurality of holes 8 of the nose pad 7 are supplied with gas through the common fourth gas supply chamber 25, and the plurality of holes 8 of the first wall 5 and the plurality of holes 8 of the nose pad 7 are not supplied with gas independently. The gas through the holes 8 in the second wall 6 is supplied independently of the gas supplied to the fourth gas supply chamber 25. In some embodiments, the fourth supply chamber 25 communicates with the plurality of holes 8 in the first wall 5, and the fifth supply chamber 26 communicates with the plurality of holes 8 in the second wall 6 and the plurality of holes 8 in the nosepiece 7. At this time, the plurality of holes 8 of the second wall 6 and the plurality of holes 8 of the nose pad 7 are supplied with gas through the common fifth gas supply chamber 26, and the plurality of holes 8 of the second wall 6 and the plurality of holes 8 of the nose pad 7 are not independently supplied with gas. The gas through the holes 8 in the first wall 5 is supplied independently of the fifth gas supply chamber 26. In some embodiments, the fourth supply plenum 25 communicates with the plurality of holes 8 in the first wall 5 and the plurality of holes 8 in the second wall 6, and the fifth supply plenum 26 communicates with the plurality of holes 8 in the nosepiece 7. At this time, the plurality of holes 8 of the first wall 5 and the plurality of holes 8 of the second wall 6 are supplied with gas through the common fourth gas supply chamber 25, and the plurality of holes 8 of the first wall 5 and the plurality of holes 8 of the second wall 6 are not independently supplied with gas. The air flow through the plurality of holes 8 in the nose pad 7 is independent of the air supply to the fourth air supply chamber 25.

In some embodiments, the eyewear may further include a temperature conditioning chamber 10 and/or a drying chamber 16. The temperature adjustment chamber 10 and the drying chamber 16 are both provided in the frame 4.

In some embodiments, the eyewear may include a temperature regulated chamber 10. The temperature-adjusting chamber 10 may include at least two temperature-adjusting chambers partitioned. Temperature regulators are arranged in the at least two temperature regulation cavities. At least two temperature adjusting chambers are respectively provided in the passages between the outlet of the gas pump 9 and the at least two gas supply chambers to respectively adjust gas parameters fed into the at least two gas supply chambers, the gas parameters including temperature values of the gas. The temperature regulator may be a semiconductor cooling plate. The outlet of the gas pump 9 may be an outlet which communicates with at least two temperature regulation chambers, respectively. The temperature regulators in the at least two temperature regulation cavities can respectively regulate the temperature value of the gas, and the regulated gas can be respectively supplied to the at least two gas supply chambers. The number of the temperature adjusting cavities is the same as that of the gas supply chambers, so that the gas output by different temperature adjusting cavities can be independently output to different gas supply chambers to enable the gas output by different gas supply chambers to be independent.

In some embodiments, the lens may include a drying chamber 16. The drying chamber 16 may include at least two drying chambers that are separated. At least two drying chambers are provided with a desiccant. At least two drying chambers are provided in the passage between the outlet of the gas pump 9 and the at least two gas supply chambers to adjust the gas parameters fed into the at least two gas supply chambers, the gas parameters including the humidity value of the gas. After the gas passes through the desiccant in the drying chamber, the humidity level of the gas is reduced. The outlet of the gas pump 9 may be an outlet which communicates with at least two drying chambers, respectively. The drying agents in the at least two drying chambers can respectively adjust the humidity value of the gas, and the adjusted gas can be respectively supplied to the at least two gas supply chambers. The number of the drying chambers is the same as that of the gas supply chambers, so that the gas output by different drying chambers can be independently output to different gas supply chambers, and the gas output by different gas supply chambers is independent. The desiccant in different drying chambers may be different so that the humidity level of the gas being reduced through different drying chambers is different. For example, different drying chambers may house different types of desiccants or different volumes of desiccants.

A temperature regulation chamber 10 is provided in the passage between the gas pump 9 and the gas supply chamber, and is capable of regulating the temperature of the gas in the passage so as to reach a preset temperature value; the drying chamber 16 is provided in a passage between the gas pump 9 and the gas supply chamber, and the humidity of the gas in the passage can be adjusted so as to reach a preset humidity value.

In some embodiments, the eyewear may further include a temperature conditioning chamber 10 and a drying chamber 16. The temperature-adjusting chamber 10 may include at least two temperature-adjusting chambers partitioned. Temperature regulators are arranged in the at least two temperature regulation cavities. The drying chamber 16 may include at least two drying chambers that are separated. At least two drying chambers are provided with a desiccant. At least two drying chambers are provided in a passage between an outlet of the gas pump 9 and at least two temperature adjusting chambers, which are respectively provided in a passage between the at least two drying chambers and the at least two gas feeding chambers, to respectively adjust gas parameters supplied into the at least two gas feeding chambers, the gas parameters including a temperature value and a humidity value of the gas. The number of the drying cavities and the number of the temperature adjusting cavities are the same as the number of the gas supply chambers, so that the gas output by different temperature adjusting cavities and different drying cavities can be independently output to different gas supply chambers, and the gas output by different gas supply chambers is independent.

In some embodiments, the eyewear may further include a temperature conditioning chamber 10 and a drying chamber 16. The temperature-adjusting chamber 10 may include at least two temperature-adjusting chambers partitioned. Temperature regulators are arranged in the at least two temperature regulation cavities. The drying chamber 16 may be provided with a desiccant. The drying chamber is provided in a passage between an outlet of the gas pump 9 and at least two temperature adjusting chambers provided in a passage between the drying chamber and at least two gas supply chambers, respectively, to adjust gas parameters supplied to the at least two gas supply chambers, respectively, the gas parameters including a temperature value of the gas. The humidity values of the gases passing through the drying chamber are adjusted in the same manner, and the humidity values of the gases in different gas supply chambers are not adjusted in the drying chamber. The number of the temperature adjusting cavities is the same as that of the gas supply chambers, so that the gas output by different temperature adjusting cavities can be independently output to different gas supply chambers to enable the gas output by different gas supply chambers to be independent.

In some embodiments, temperature regulated chamber 10 includes three temperature regulated chambers separated. The three temperature regulation cavities are respectively a first temperature regulation cavity 11, a second temperature regulation cavity 12 and a third temperature regulation cavity 13. The first temperature adjustment chamber 11 is connected between the gas pump 9 and the first gas supply chamber 22 through a hose 37, the second temperature adjustment chamber 12 is connected between the gas pump 9 and the second gas supply chamber 23 through a hose 37, and the third temperature adjustment chamber 13 is connected between the gas pump 9 and the third gas supply chamber 24 through a hose 37. In some embodiments, drying chamber 16 includes three separate drying chambers. The three drying chambers are a first drying chamber 17, a second drying chamber 18 and a third drying chamber 19. The first drying chamber 17 is connected between the gas pump 9 and the first gas supply chamber 22 through a hose 37, the second drying chamber 18 is connected between the gas pump 9 and the second gas supply chamber 23 through a hose 37, and the third drying chamber 19 is connected between the gas pump 9 and the third gas supply chamber 24 through a hose 37. In some embodiments, temperature regulated chamber 10 includes three temperature regulated chambers separated. The three temperature regulation cavities are respectively a first temperature regulation cavity 11, a second temperature regulation cavity 12 and a third temperature regulation cavity 13. The drying chamber 16 includes three separate drying chambers. The three drying chambers are a first drying chamber 17, a second drying chamber 18 and a third drying chamber 19. Wherein, a first drying cavity 17 and a first temperature adjusting cavity 11 are sequentially arranged between the gas pump 9 and the first gas supply chamber 22 through a hose 37, a second drying cavity 18 and a second temperature adjusting cavity 12 are sequentially arranged between the gas pump 9 and the second gas supply chamber 23 through a hose 37, and a third drying cavity 19 and a third temperature adjusting cavity 13 are sequentially arranged between the gas pump 9 and the third gas supply chamber 24 through a hose 37.

For this purpose, the gas entering the gas supply chamber can be adjusted to a desired temperature by means of a correspondingly arranged temperature control chamber and can be adjusted to a desired humidity by means of a correspondingly arranged drying chamber.

In some embodiments, the eyewear further comprises an arrangement of temperature conditioning chambers 10 and drying chambers 16. Specifically, the temperature regulation chamber 10 includes two temperature regulation chambers partitioned. The two temperature regulation cavities are a fourth temperature regulation cavity 14 and a fifth temperature regulation cavity 15 respectively. The fourth temperature adjustment chamber 14 is connected to the fourth gas supply chamber 25 through a hose 37, and the fifth temperature adjustment chamber 15 is connected to the fifth gas supply chamber 26 through a hose 37, while the gas pump 9 is connected to the fifth gas supply chamber 26 through a hose 37. The drying chamber 16 includes two separate drying chambers. The two drying chambers are respectively a fourth drying chamber 20 and a fifth drying chamber 21, the fourth drying chamber 20 is connected and arranged between the gas pump 9 and the fourth gas supply chamber 25 through a hose 37, and the fifth drying chamber 21 is connected and arranged between the gas pump 9 and the fifth gas supply chamber 26 through a hose 37. In some embodiments, the temperature regulated chamber 10 includes two temperature regulated chambers that are separated. The two temperature regulation cavities are respectively a first temperature regulation cavity 11, a second temperature regulation cavity 12 and a third temperature regulation cavity 13. The drying chamber 16 includes three separate drying chambers. The three drying chambers are a first drying chamber 17, a second drying chamber 18 and a third drying chamber 19. Wherein, a first drying cavity 17 and a first temperature adjusting cavity 11 are sequentially arranged between the gas pump 9 and the first gas supply chamber 22 through a hose 37, a second drying cavity 18 and a second temperature adjusting cavity 12 are sequentially arranged between the gas pump 9 and the second gas supply chamber 23 through a hose 37, and a third drying cavity 19 and a third temperature adjusting cavity 13 are sequentially arranged between the gas pump 9 and the third gas supply chamber 24 through a hose 37. In this embodiment, similarly, gases having desired temperatures and humidities can be supplied to the fourth gas supply chamber 25 and the fifth gas supply chamber 26, respectively. In some embodiments, a temperature conditioning chamber 10 and a drying chamber 16 may be provided in the eyewear. In some embodiments, only the temperature conditioning chamber 10, or only the drying chamber 16, may be provided in the eyewear. In some embodiments, the temperature adjustment chamber 10 and the drying chamber 16 are provided in the eyeglasses such that the positions of the two chambers between the gas pump 9 and the gas supply chamber can be adjusted back and forth interchangeably. In some embodiments, the temperature adjustment chamber 10 and the drying chamber 16 are disposed in the eyewear, the temperature adjustment chamber 10 is disposed downstream of the drying chamber 16, and the gas output from the gas pump 9 passes through the drying chamber 16, the temperature adjustment chamber 10, and then the gas supply chamber.

Further, the glasses may comprise a control unit 27, which is arranged within the frame 4. The control unit 27 is electrically connected to the temperature regulator to control the temperature regulator.

A switch is provided on a path that feeds the at least two air supply chambers, and a control unit 27 is connected to the switch to control the opening and closing of the path.

In some embodiments, a control unit 27 is provided within the frame 4. The control unit 27 is electrically connected to the temperature regulators in the three temperature regulation chambers, respectively, to control the temperature regulators to regulate the temperature of the gas passing therethrough. In this embodiment, a first switch 28 is disposed on a flexible tube 37 between the temperature adjusting chamber 10 and the first air supply chamber 22, a second switch 29 is disposed on a flexible tube 37 between the temperature adjusting chamber 10 and the second air supply chamber 23, a third switch 30 is disposed on a flexible tube 37 between the temperature adjusting chamber 10 and the third air supply chamber 24, and the control unit 27 is electrically connected to the switches to control the switches to be turned on or off. After the temperature of the gas in different temperature adjusting cavities of the temperature adjusting chamber is adjusted, the corresponding switch is controlled to be opened so that the passage passing through the temperature adjusting cavities is opened. The passage through the temperature regulation chamber refers to a passage through which the gas pump 9 passes to the corresponding gas supply chamber.

By providing the control unit 27, it is possible to realize automated control of the opening of the passages of the gas pumps 9 to the respective gas supply chambers and the gas parameters of the gas of the respective passages.

In some embodiments, the eyewear includes a sensor. The control unit 27 may be electrically connected to the sensors to control the temperature regulators and the switches according to the output parameters of the sensors. In this way, the control unit 27 can control the temperature regulator and the switch according to the feedback of the sensor, and realize automatic adjustment.

For the sensor, it may include at least one of a temperature sensor and a humidity sensor. The sensor is disposed on at least one of the first wall 5 and the second wall 6. The temperature sensor is used for detecting the temperature of the first wall and/or the second wall, and the humidity sensor is used for detecting the humidity of the first wall and/or the second wall. A sensor may be provided on at least one of the first wall 5 and the second wall 6 for detecting temperature and humidity values at the location of the first wall 5 and/or the second wall 6.

In some embodiments, the sensors include a temperature sensor and a humidity sensor. A first temperature sensor 33 and a first humidity sensor 35 are provided on the first wall 5, and a second temperature sensor 34 and a second humidity sensor 36 are provided on the second wall 6. The eyewear of this embodiment may implement corresponding automated adjustment controls in the following applications.

In summer, the weather is hot and humid, when the AR glasses are put on the nose bridge, the nose support 7 bears the weight of the glasses, the glasses are tightly contacted with the skin of the nose and are airtight, and the moist air can not come out from the nose support, so that the feeling is very uncomfortable. In this case, if very dry, air at a temperature slightly below body temperature can flow out of the contact surface, which is very comfortable. Specifically, the method comprises the following steps: the control unit 27 controls the third switch 30 to be turned on and controls the temperature regulator in the third temperature regulation chamber 13 so that the temperature of the gas passing through the third temperature regulation chamber 13 reaches 35 to 36.5 ℃. The air sucked by the air pump 9 enters the third drying cavity 19 of the drying chamber 16, is dried, enters the third temperature adjusting cavity 13 to adjust the temperature, then enters the third air supply chamber 24, and is output from the plurality of holes 8 on the nose pad 7, so that the nose pad 7 blows outwards. After a certain period of operation, which makes the nose pad 7 and the bridge of the nose drier, the third switch 30 can be closed by the control unit 27 and the operation of the thermostat in the third thermostatic chamber 13 can be stopped.

When the first surface 2 and the second surface 3 of the lens have a temperature difference, water accumulation occurs.

When the temperature of the second surface detected by the second temperature sensor 34 is 5 c higher than the temperature of the first surface 2 detected by the first temperature sensor 33 and the humidity of the second surface 3 detected by the second humidity sensor 36 reaches 30%, the control unit 27 controls to open the second switch 29 and controls the temperature regulator in the second temperature adjusting chamber 12 such that the temperature of the gas passing through the second temperature adjusting chamber 12 reaches 35-36.5 c. The air fed by the air pump 9 is dried by the second drying chamber 18, enters the second temperature adjustment chamber 12, enters the second air supply chamber 23 and is discharged through the plurality of holes 8 in the second wall 6, so that the air is blown from the second surface 3 to the facial space of the user. When the humidity of the second surface 3 detected by the second humidity sensor 36 drops below 5%, the control unit 27 controls the second switch 29 to be closed to stop blowing, so that accumulated water is removed.

When the temperature of the first surface 2 detected by the first temperature sensor 33 is 5 ℃ higher than the temperature of the second surface 3 detected by the second temperature sensor 34 and the humidity of the first surface 2 detected by the first humidity sensor 35 reaches 30%, the control unit 27 controls to open the first switch 28 and controls the temperature regulator in the first temperature regulation chamber 11 so that the temperature of the gas passing through the first temperature regulation chamber 11 reaches 35-36.5 ℃. The gas fed by the gas pump 9 is dried by the first drying chamber 17, enters the first temperature adjustment chamber 11, enters the first gas feed chamber 22 and is discharged through the plurality of holes 8 in the first wall 5, thus blowing the first surface 2. When the humidity of the first surface 2 detected by the first humidity sensor 35 drops below 5%, the control unit 27 controls the first switch 28 to be closed to stop blowing, so that accumulated water is removed.

When the humidity of the first surface 2 detected by the first humidity sensor 35 reaches 30%, the control unit 27 controls the first switch 28 to be turned on, receives the temperature value of the external environment detected by the first temperature sensor 33, and adjusts the temperature regulator in the first temperature adjustment cavity 11 according to the temperature value, so that the temperature of the gas passing through the first temperature adjustment cavity 11 reaches the temperature value. The gas discharged from the gas pump 9 is dried by the first drying chamber 17, enters the first temperature adjusting chamber 11, enters the first gas supply chamber 22, and is discharged from the plurality of holes 8 on the first wall 5, so that the air blowing is realized. When the humidity of the first surface detected by the first humidity sensor 35 falls below 5%, the control unit 27 controls to close the first switch 28 and stop the blowing. The process completes the de-icing.

In some embodiments, a third temperature sensor 38 and a third humidity sensor 39 are provided on the first wall 5, and a fourth temperature sensor 40 and a fourth humidity sensor 41 are provided on the second wall 6. The glasses also comprise a control unit 27 and an arrangement of switches. The temperature adjusting chamber 10 is disposed downstream of the drying chamber 16, a fourth switch 31 is provided on a hose 37 between the temperature adjusting chamber 10 and the fourth air feeding chamber 25, and a fifth switch 32 is provided on the hose 37 between the temperature adjusting chamber 10 and the fifth air feeding chamber 26.

In this embodiment, the lenses become blurred when the glasses are worn from the outside, where the outside is cooler, to the inside, where the temperature is higher. At this time, the control unit 27 may control the turn-on of the fourth and fifth switches 31 and 32 and control the temperature regulators in the fourth and fifth temperature regulation chambers 14 and 15 such that the temperature of the gas passing through the regulation chambers reaches 35 to 36.5 ℃. The gas inputted by the gas pump 9 is dried by the fourth drying chamber 20 and the fifth drying chamber 21, and then enters the corresponding fourth temperature adjusting chamber 14 and the fifth temperature adjusting chamber 15 for temperature adjustment. And respectively enters the corresponding fourth air supply chamber 25 and the fifth air supply chamber 26 and is discharged through the corresponding holes 8 on the first wall 5 and the second wall 6, so that water vapor on the lens can be removed, and the lens is clear.

In some embodiments, the outer surface of the first wall 5 of the lens is further outward than the first surface 2. The axial direction of the plurality of holes 8 provided in the first wall 5 intersects the first surface 2 so that the gas is blown towards the first surface 2 through the plurality of holes 8 provided in the first wall 5. The further outward arrangement may facilitate providing space for opening a plurality of holes 8 capable of blowing air towards the first surface 2.

In particular, the plurality of holes 8 provided in the first wall 5 enclose a circle so that the gas is blown towards a predetermined area of the first surface 2 through the plurality of holes 8 provided in the first wall 5. The preset area may be a central area of the first surface. Such as a rectangular area or a circular area surrounding a center point. By the arrangement, air can be blown to a specific area. So that the gas can form annular turbulence outside the first surface 2, and the gas flow is accelerated.

In some embodiments, the outer surface of the first wall 5 is further outward than the first surface 2. The holes 8 provided in the first wall 5 are at the same distance from the first surface 2, and the holes 8 provided in the first wall 5 are arranged axially through a set straight line passing through the center of the first surface 2 and extending along a perpendicular to the tangent plane where the center is located. Through this setting, can make the wind that a plurality of holes 8 blew off pass through the region of setting for the straight line, the wind that a plurality of holes 8 blew off is in central zone intersection, can realize the homogeneity.

In some embodiments, the plurality of holes formed in the second wall 6 form a circle, and the plurality of holes 8 formed in the second wall 6 have an axial direction parallel to a perpendicular direction of the outer surface of the second wall 6 around the holes 8. Blowing toward the user's face may be accomplished. At the same time, it may blow on the second surface 3 of the lens upon reflection.

In some embodiments, the nose piece 7 and the second wall 6 are removably connected. Specifically, be equipped with on the nose holds in the palm 7 protruding, be equipped with on the second wall 6 with this protruding draw-in groove that matches, both can dismantle the connection, be convenient for hold in the palm 7 the nose that carries out the renewal or carry out the omnidirectional after dismantling to the nose and maintain and clean. And, the outer cover of nose pad 7 establishes one deck dustcoat, and the material of nose pad 7 is selected from one in organic glass, rubber and the hard sponge, and the dustcoat is selected from one in ice silk, silk. The nose pad 7 is provided with a groove, and the outer cover is provided with an elastic free end matched with the groove. The materials are skin-friendly materials, so that the wearing comfort is improved.

The present disclosure also provides a control method for glasses. With reference to fig. 1-5, the eyewear may include an optical element 1, a frame 4, and a nose pad 7. The optical element 1 is fixedly connected within the frame 4. The frame 4 comprises a first wall 5 facing outwards and a second wall 6 facing inwards, and the nose pads 7 are connected to the second wall 6. The spectacles further comprise a gas pump 9, a drying chamber 16, a temperature adjusting chamber 10 and three gas supply chambers which are communicated in sequence and are arranged in the frame body 4. The inlet of the gas pump 9 communicates with an opening in the frame 4. The temperature adjusting chamber 10 comprises three temperature adjusting chambers which are separated from each other, a temperature adjuster is arranged in each temperature adjusting chamber to adjust the temperature of the temperature adjusting chamber, each temperature adjusting chamber is communicated with one gas supply chamber, and the three gas supply chambers are communicated with the plurality of holes 8 formed in the first wall 5, the plurality of holes 8 formed in the second wall 6 and the plurality of holes 8 formed in the nose support 7 to form a first passage, a second passage and a third passage from the gas pump 9 to the three gas supply chambers respectively. The eyeglasses further comprise a control unit 27 and a switch arranged in the frame 4, the switch being arranged between the temperature adjustment chamber and the air supply chamber of the three passages to control the opening and closing of the three passages. The spectacles further comprise a first temperature sensor 33 and a first humidity sensor 35 arranged on the first wall 5 and a second temperature sensor 34 and a second humidity sensor 36 arranged on the second wall 6.

The method comprises the following steps: based on the control commands received by the control unit 27, the temperature of the temperature regulator is adjusted and/or the on/off of the switch is controlled to adjust the gas parameters of the three gas supply chambers, respectively. The method can realize automatic feedback adjustment of blowing.

In some embodiments, it is also possible to receive manual operation commands and send control commands to the control unit 27.

In some embodiments, the lens does not define the interior of the drying chamber 16, so long as the drying chamber 16 is capable of having the effect of drying the gas. A method of controlling the eyeglasses will be described. Wherein the passage of the gas pump 9 to the first gas supply chamber 22 is a first passage, the passage of the gas pump 9 to the second gas supply chamber 23 is a second passage, and the passage of the gas pump 9 to the third gas supply chamber 24 is a third passage.

In a specific first method, the method includes:

in response to opening the third passage, the temperature of the thermostat on the third passage is set to the first temperature or the temperature of the thermostat on the third passage is adjusted in accordance with the data collected by the second temperature sensor so that the data collected by the second temperature sensor 34 is the first temperature;

in response to closing the third passage, the thermostat on the third passage is closed.

The first temperature may be 35-36.5 ℃.

In the method, the control unit 27 controls the temperature regulator in the third temperature regulation chamber 13 in response to the third switch 30 being turned on, for example, in response to an operation command to turn on the third switch 30, so that the temperature of the gas passing through the third temperature regulation chamber 13 reaches 35 to 36.5 ℃. For example, the temperature regulator adjusts the temperature of the third temperature adjustment chamber 13 to the first temperature by setting the temperature of the temperature regulator in the third temperature adjustment chamber 13 to the first temperature. Alternatively, for example, the temperature around the second temperature sensor is derived from data collected by a second temperature sensor provided on the second wall 6, the temperature around the second temperature sensor being indicative of the temperature of the second wall 6. The temperature of the temperature regulator in the third temperature regulation chamber 13 is adjusted according to the data collected by the second temperature sensor so that the temperature collected by the second temperature sensor becomes the first temperature. The air sucked by the air pump 9 enters the drying chamber 16, is dried, enters the third temperature adjusting chamber 13 for temperature adjustment, enters the third air supply chamber 24, and is output through the plurality of holes 8 on the nose pad 7, so that the nose pad 7 blows outwards. After a certain period of operation, which makes the nose pad 7 and the bridge of the nose drier, the third switch 30 may be closed in response to an operation command and the operation of the thermostat in the third thermostatic chamber 13 may be stopped by the control unit 27. The method can blow air outwards through the nose support 7 to blow air at the nose bridge.

In some embodiments, in response to the data collected by the second temperature sensor 34 being higher than the data collected by the first temperature sensor 33 by a first temperature set point and the data collected by the second humidity sensor 36 being not less than the first humidity set point, the second pathway is opened with the temperature of the thermostat on the second pathway set to the first temperature or the temperature of the thermostat on the second pathway is adjusted based on the data collected by the second temperature sensor to bring the data collected by the second temperature sensor to the first temperature;

in response to the data collected by second humidity sensor 36 not being greater than the second humidity set point, the second path is closed and the thermostat on the second path is closed.

In the method, the first temperature setting may be 5 ℃, the first humidity setting 30%, and the second humidity setting 5%.

Specifically, when the temperature of the second surface 3 detected by the second temperature sensor 34 is 5 ℃ higher than the temperature of the first surface 2 detected by the first temperature sensor 33, and the humidity of the second surface 3 detected by the second humidity sensor 36 reaches 30%, the control unit 27 controls to open the second switch 29 and controls the temperature regulator in the second temperature regulation chamber 12 so that the temperature of the gas passing through the regulation chamber reaches 35-36.5 ℃. For example, the temperature regulator adjusts the temperature of the second temperature adjustment chamber 12 to the first temperature by setting the temperature of the temperature regulator in the second temperature adjustment chamber 12 to the first temperature. Alternatively, for example, the temperature around the second temperature sensor is derived from data collected by a second temperature sensor provided on the second wall 6, the temperature around the second temperature sensor being indicative of the temperature of the second wall 6. The temperature of the temperature regulator in the second temperature regulation cavity 12 is adjusted according to the data collected by the second temperature sensor, so that the temperature collected by the second temperature sensor is the first temperature. The gas fed by the gas pump 9 is dried by the drying chamber 16, enters the second temperature adjustment chamber 12, enters the second gas feeding chamber 23 and is discharged through the plurality of holes 8 in the second wall 6. When the humidity of the second surface 3 detected by the second humidity sensor 36 drops below 5%, the control unit 27 controls the second switch 29 to be closed to stop blowing, so that accumulated water is removed.

In some embodiments, in response to the data collected by the first temperature sensor 33 being higher than the data collected by the second temperature sensor 34 by a first temperature set point and the data collected by the first humidity sensor 35 being not less than the first humidity set point, the first pathway is opened, the temperature of the thermostat on the first pathway is set to a first temperature or the temperature of the thermostat on the first pathway is adjusted according to the data collected by the first temperature sensor 33 so that the data collected by the first temperature sensor 33 is the first temperature;

in response to the data collected by first humidity sensor 35 being not greater than the second humidity set point, the first pathway is closed and the temperature regulator on the first pathway is closed.

Wherein the first temperature setting may be 5 ℃, the first humidity setting 30%, and the second humidity setting 5%.

Specifically, when the temperature of the first surface 2 detected by the first temperature sensor 33 is 5 ℃ higher than the temperature of the second surface 3 detected by the second temperature sensor 34, and the humidity of the first surface 2 detected by the first humidity sensor 35 reaches 30%, the control unit 27 controls to open the first switch 28 and controls the temperature regulator in the first temperature regulation chamber 11 so that the temperature of the gas passing through the regulation chamber reaches 35-36.5 ℃. For example, the temperature regulator adjusts the temperature of the first temperature adjustment chamber 11 to the first temperature by setting the temperature of the temperature regulator in the first temperature adjustment chamber 11 to the first temperature. Alternatively, for example, the temperature around the first temperature sensor is derived from data collected by a second temperature sensor provided on the first wall 5, the temperature around the first temperature sensor being indicative of the temperature of the first wall 5. The temperature of the temperature regulator in the first temperature regulation cavity 11 is adjusted according to the data collected by the first temperature sensor so that the temperature collected by the first temperature sensor is the first temperature. After the gas input by the gas pump 9 passes through the drying chamber 16 for drying, the gas enters the first temperature adjusting chamber 11, enters the first gas supply chamber 22, and is discharged through the plurality of holes 8 on the first wall 5, so that the blowing to the first surface 2 is realized, when the humidity of the first surface 2 detected by the first humidity sensor 35 is reduced to be lower than 5%, the control unit 27 controls the first switch 28 to be closed to stop the blowing, so that the accumulated water is removed.

In some embodiments, in response to the data collected by the first humidity sensor 35 being not less than the first humidity set point, the first pathway is opened, and the temperature of the thermostat on the first pathway is set to be the same as the data collected by the first temperature sensor 33;

in response to the data collected by first humidity sensor 35 being not greater than the second humidity set point, the first pathway is closed and the temperature regulator on the first pathway is closed.

Wherein the first humidity set point is 30% and the second humidity set point is 5%.

Specifically, when the humidity of the first surface 2 detected by the first humidity sensor 35 reaches 30%, the control unit 27 controls the first switch 28 to be turned on, receives the temperature value detected by the first temperature sensor 33, and adjusts the temperature regulator in the first temperature adjustment cavity 11 according to the temperature value, so that the temperature of the gas passing through the adjustment cavity reaches the temperature value. For example, the temperature regulator adjusts the temperature of the first temperature adjustment chamber 11 to the first temperature by setting the temperature of the temperature regulator in the first temperature adjustment chamber 11 to the first temperature. The gas discharged from the gas pump 9 is dried by the drying chamber 16, enters the first temperature adjusting chamber 11, enters the first gas supply chamber 22, and is discharged from the plurality of holes 8 on the first wall 5, so that the air blowing is realized. When the humidity of the first surface 2 detected by the first humidity sensor 35 falls below 5%, the control unit 27 controls to close the first switch 28 and stop the blowing. The process completes the de-icing.

Claims (4)

1. An eyeglass, comprising:

an optical element having an outwardly facing first surface and an inwardly facing second surface;

the frame body comprises a first wall facing the same direction as the first surface and a second wall facing the same direction as the second surface, and the optical element is fixedly connected with the frame body;

a nose pad connected to the second wall;

the at least two air supply chambers are arranged in the frame and are respectively communicated with at least two of the plurality of holes formed in the first wall, the plurality of holes formed in the second wall and the plurality of holes formed in the nose support;

and the gas pump is arranged in the frame body, the inlet of the gas pump is communicated with the opening in the frame body, and the outlet of the gas pump is respectively communicated with the at least two gas supply chambers so as to respectively adjust the gas parameters of the at least two gas supply chambers.

2. The eyeglasses according to claim 1, characterized in that they comprise:

a temperature adjustment chamber disposed in the frame, the temperature adjustment chamber including at least two temperature adjustment chambers separated from each other, a temperature adjuster being disposed in each of the at least two temperature adjustment chambers, the at least two temperature adjustment chambers being respectively disposed in a passage between an outlet of the gas pump and the at least two gas supply chambers to respectively adjust gas parameters supplied into the at least two gas supply chambers, the gas parameters including temperature values of the gas; and/or a drying chamber disposed within the frame, the drying chamber comprising at least two separate drying chambers, each of the at least two drying chambers being provided with a desiccant, the at least two drying chambers being disposed in a passage between an outlet of the gas pump and the at least two gas feed chambers to regulate a gas parameter fed into the at least two gas feed chambers, the gas parameter comprising a humidity value of the gas;

the glasses comprise a control unit which is arranged in the frame body, and the control unit is electrically connected with the temperature regulator to control the temperature regulator; the passages for supplying the gas to the at least two gas supply chambers are provided with switches, and the control unit is connected with the switches to control the on-off of the passages;

the glasses comprise a sensor, and the control unit is electrically connected with the sensor to control the temperature regulator and the switch according to the output parameter of the sensor;

the sensor comprises at least one of a temperature sensor and a humidity sensor; the sensor is disposed on at least one of the first wall and the second wall;

the outer surface of the first wall is more outward than the first surface, and the axial directions of the plurality of holes formed in the first wall are intersected with the first surface so that gas is blown to the first surface through the plurality of holes formed in the first wall;

a circle of holes formed in the first wall is formed by surrounding, so that gas is blown to a preset area of the first surface through the holes formed in the first wall;

the nose support is detachably connected with the second wall;

the nose support is provided with a bulge, the second wall is provided with a clamping groove matched with the bulge, and the air supply chamber and a plurality of holes formed in the nose support pass through the bulge;

the nose support is covered by a layer of outer cover, the nose support is made of one of organic glass, rubber and hard sponge, and the outer cover is made of one of ice silk and silk;

the nose pad is provided with a groove, and the outer cover is provided with an elastic free end matched with the groove.

3. The eyeglasses according to claim 1, characterized in that the outer surface of said first wall is more external than said first surface, the holes made in said first wall are at the same distance from said first surface, and the axial direction of the holes made in said first wall is arranged to pass through a set straight line passing through the center of said first surface and extending along a perpendicular to a tangent plane to which said center lies.

4. The eyeglasses according to claim 1, wherein the plurality of holes formed in the second wall define a circle, and wherein the plurality of holes formed in the second wall have an axial direction parallel to a direction perpendicular to the outer surface of the second wall around which the holes are formed.

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