TW202006427A - Intelligent glasses - Google Patents

Abstract

The present invention provides intelligent glasses including a glasses body, a nose pad, and a miniature vortex tube. The nose pad is configured on the glasses body. The miniature vortex tube is configured on the glasses body and coupled to the nose pad. The miniature vortex tube selectively decreases or increases the temperature of the nose pad. An ambient temperature module for sensing ambient temperature can be configured on the glasses body or a portable device connected to the glasses body. While the ambient temperature varies dramatically, the ambient temperature module sends a signal to drive the miniature vortex tube to change the temperature of the nose pad gently. By wearing the smart glasses of the present invention, the user can prevent excessive temperature changes to irritate the nose, and further the symptoms of rhinitis is relieved.

Description

Smart glasses

The invention relates to smart glasses, in particular to smart glasses by adjusting the temperature of the nose pad to relieve the nasal symptoms caused by temperature fluctuations.

Vasomotor rhinitis is a type of non-allergic rhinitis, which, like allergic rhinitis, can cause nasal congestion, nasal discharge, or sneezing. The difference in physiological mechanism is that vasomotor rhinitis is not an overreaction of the patient's immune system, but the patient's nasal mucosa contains too much vascular tissue or the blood vessels are overly sensitive. When normal people suddenly breathe high-temperature or low-temperature air, the blood vessels of the nasal mucosa tissue dilate, increasing the blood flow and secreting an appropriate amount of rhinorrhea to avoid the air directly affecting the temperature and humidity of the upper and lower respiratory tract. However, the nasal mucosa of patients with vasomotor rhinitis overreacts to a small temperature difference, and the result of a large amount of secreted nasal discharge is serious nasal congestion or nasal discharge.

Since temperature is not a foreign antigen, many antiallergic drugs and therapies on the market are not suitable for patients with vasomotor rhinitis. On the contrary, in clinical practice, patients with long-term allergic rhinitis are prone to vasomotor rhinitis, so that patients who originally only had allergic reactions to antigens such as dust mites or pollen also began to overreact to temperature changes. Therefore, more than 20% of the Chinese may be patients or high-risk groups of vasomotor rhinitis.

For patients, how to avoid or improve the symptoms of rhinitis in a short time is an important issue. It is the most difficult way to continue wearing a mask to initially cushion the hot and cold air directly into the nose. However, in general, the effect of masks is limited, and many places or behaviors are not suitable for wearing masks. In addition, medical use of vasoconstrictors or steroids to slow rhinitis, but the drug has a certain degree of negative effects on the body. Therefore, how to proceed from different angles to improve the discomfort of patients with rhinitis is an urgent need to break through.

In view of this, the present invention proposes a pair of smart glasses, which can reduce the irritation of the nose by the temperature difference and relieve the symptoms of the nose by adjusting the temperature of the nose pads of the glasses to conduct heat to the nose.

The smart glasses proposed by the present invention include a glasses body, a nose pad disposed on the glasses body, and a micro vortex tube. The micro vortex tube is disposed on the body of the eyeglasses and coupled to the nose pad. The micro vortex tube selectively lowers or raises the temperature of the nose pad.

In a specific embodiment, the eyeglass body includes a frame and a temple. The nose pad is arranged on the frame, the micro vortex tube is arranged on the temple, and the frame is respectively coupled to the nose pad and the micro vortex tube.

In a specific embodiment, the lens frame includes a heat pipe for coupling the nose pad and the micro vortex tube respectively. The micro vortex tube reduces the temperature of the nose pads or raises the temperature through the heat pipe.

In a specific embodiment, the smart glasses further include a communication module disposed on the glasses body and coupled to the micro vortex tube, for wirelessly connecting a portable device. The portable device is provided with an ambient temperature module for sensing the change of an ambient temperature. When the ambient temperature drops at a rate that exceeds a first temperature change, the ambient temperature module sends a cooling signal.

In a specific embodiment, after the micro vortex tube receives the cooling signal through the communication module, the micro vortex tube cools the nose pad at a second temperature change rate.

In a specific embodiment, the smart glasses further include an ambient temperature module, which is disposed on the glasses body and coupled to the micro vortex tube. The ambient temperature module is used to sense changes in an ambient temperature. When the ambient temperature drops at a rate that exceeds a first temperature change rate, the ambient temperature module sends a cooling signal.

In a specific embodiment, after the micro vortex tube receives the cooling signal, the micro vortex tube cools the nose pad at a second temperature change rate.

In a specific embodiment, the first temperature change rate is greater than the second temperature change rate.

In a specific embodiment, when the ambient temperature rises above a first temperature change rate, the ambient temperature module sends a warming signal to control the micro vortex tube so that the nose pad raises the temperature at a second temperature change rate.

In a specific embodiment, the first temperature change rate is 0.2 degrees Celsius per second (0.2°C/sec).

In another specific embodiment, the first temperature change rate is 0.3 degrees Celsius per second (0.3°C/sec).

In a specific embodiment, the second temperature change rate is 0.2 degrees Celsius per minute (0.2°C/min).

In a specific embodiment, the temperature of the nose pad is not lower than 15°C.

In a specific embodiment, the smart glasses further include a nose pad temperature module coupled to the micro vortex tube for sensing the temperature of the nose pad or the heat pipe, and then send a signal to control the micro vortex tube to adjust the working efficiency.

In a specific embodiment, the smart glasses further include a humidity sensing module, which is disposed on the glasses body and electrically coupled to the micro vortex tube. When the humidity sensing module detects a change in ambient humidity, the humidity sensing module controls the micro vortex The tube lowers or raises the temperature of the nose pads for a period of time.

In a specific embodiment, the smart glasses are further provided with a vibration module coupled to the micro vortex tube. When the vibration module detects the vibration, the vibration module controls the micro vortex tube through the communication module to make the nose support according to the ambient temperature module Raise the temperature at a third temperature change rate.

In a specific embodiment, the portable device is further provided with a vibration module. When the vibration module detects vibration, the vibration module controls the micro vortex tube through the communication module according to the ambient temperature module to make the nose pad Three temperature change rates increase the temperature.

In a specific embodiment, the smart glasses are further provided with a human body temperature module coupled to the micro vortex tube. When the human body temperature module detects the human body temperature, the human body temperature module controls the micro vortex tube to enable the nose support according to the ambient temperature module Raise the temperature at a third temperature change rate.

In a specific embodiment, the glasses system is vision correction glasses, modeling glasses, sunglasses, 3D glasses, virtual reality glasses, goggles, working goggles, diving goggles, wind goggles or ski goggles.

In a specific embodiment, the material of the nose pad includes at least one of metal, ceramic, carbon fiber and silicone.

In summary, the smart glasses of the present invention can selectively change the temperature of the nose pads to prevent excessive temperature changes from irritating the nose and alleviating the symptoms of the nose of patients with rhinitis. The arrangement of the heat pipe enables the cold air and hot air produced by the micro vortex tube to communicate with the nose pads in the form of thermal energy to achieve efficient temperature conduction. The ambient temperature module continuously detects the ambient temperature and sends a temperature signal to the micro vortex tube when the temperature changes rapidly, so that the micro vortex tube changes the temperature of the nose pad at a relatively slow rate. Use the rest of the sensing modules to send signals to the ambient temperature module to adjust the temperature of the nose pads in real time and accurately under various conditions.

1‧‧‧ glasses body

11‧‧‧Mirror feet

12‧‧‧Communication module

13‧‧‧Nose support temperature module

14‧‧‧Ambient temperature module

15‧‧‧Humidity sensor module

16‧‧‧Vibration module

17‧‧‧Body temperature module

18‧‧‧Frame

19‧‧‧Heat pipe

100‧‧‧Smart Glasses

2‧‧‧ nose pads

3‧‧‧mini vortex tube

30‧‧‧Gas inlet

33‧‧‧ vortex chamber

37‧‧‧cool air outlet

38‧‧‧Hot gas outlet

39‧‧‧Demand gas export

4‧‧‧Portable device

FIG. 1 is a schematic diagram of a specific embodiment of smart glasses according to the present invention.

2 is a functional block diagram of an embodiment of smart glasses according to the present invention.

3 is a functional block diagram of another embodiment of smart glasses according to the present invention.

FIG. 4 is a functional block diagram of an embodiment of a method for controlling a micro vortex tube according to the present invention.

FIG. 5 is a schematic diagram of another embodiment of smart glasses according to the present invention.

In order to make the advantages, spirit and features of the present invention easier and clearer to understand, detailed description and discussion will follow with embodiments and reference to the accompanying drawings. It is worth noting that these embodiments are only representative embodiments of the present invention, and the specific methods, devices, conditions, materials, etc. exemplified therein are not intended to limit the present invention or the corresponding embodiments.

In the description of this specification, the description referring to the terms “a specific embodiment”, “another specific embodiment” or “partial specific embodiment” means that the specific features, structures, materials or characteristics described in conjunction with the embodiment include In at least one embodiment of the invention. In this specification, the schematic representation of the above terms does not necessarily refer to the same embodiment. Moreover, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments.

In the description of the present invention, it should be understood that the terms "portrait, landscape, top, bottom, front, back, left, right, top, bottom, inner, outer" and other indications are based on the drawings The orientation or positional relationship shown is only for the convenience of describing the present invention and simplifying the description, rather than indicating or implying that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore cannot be understood as a limit.

Please refer to Figure 1. FIG. 1 is a schematic diagram of a specific embodiment of smart glasses 100 according to the present invention. The smart glasses 100 proposed by the present invention include a glasses body 1, a nose pad 2 disposed on the glasses body 1, and a micro vortex tube 3. The micro vortex tube 3 is disposed on the eyeglass body 1 and coupled to the nose pad 2, and the micro vortex tube 3 selectively lowers or raises the temperature of the nose pad 2. The micro vortex tube 3 may be hidden inside the eyeglass body 1 or partially exposed outside the eyeglass body 1. In the drawings of the present invention, for the sake of clarity, the micro vortex tube 3 is not shown with a broken line. In addition, the micro vortex tube 3 can work on its own, or it can be activated by receiving signals from a microprocessor configured on the smart glasses 100 and receiving other input devices or modules.

In a specific embodiment, the eyeglass body 1 includes a frame 18 and a temple 11. The nose pad 2 is disposed on the frame 18, the micro vortex tube 3 is disposed on the temple 11, and the frame 18 is coupled to the nose pad 2 and the micro vortex tube 3, respectively. The micro vortex tube 3 may be hidden inside the temple 11 or partially exposed outside the temple 11.

In practical applications, the micro vortex tube 3 includes a gas inlet 30, a nozzle, a vortex chamber 33, a hot gas outlet 38, and a cold gas outlet 37. After the micro vortex tube 3 is activated, air is sucked from the gas inlet 30 and compressed. Then the compressed air enters the nozzle, expands and accelerates in the nozzle, and then enters the vortex chamber 33 at a speed of about 1,000,000 rpm in a tangential direction. When the airflow rotates at high speed in the vortex chamber 33, it is separated into two parts of airflow with unequal temperature after vortex transformation. The temperature of the airflow inside and outside the vortex chamber 33 is high and advances toward the trailing end of the vortex chamber 33. Therefore, a valve is provided at the hot gas outlet 38 at the trailing end of the vortex chamber 33 to collect the formed hot gas. The other part of the airflow returns from the inside of the vortex tube 33 and advances toward the cool air outlet 37. During the return process, the air continues to rotate, so that the heat energy continues to be carried by the outer airflow to the hot air outlet 38, while the temperature of the inner airflow is getting lower and lower to form cold air, and finally the cold air is output from the cold air outlet 37.

In principle, the micro vortex tube 3 leads the cold air and the hot air to the outlets in different directions, but in practical applications, the cold air and the hot air can be directed to the same direction by valves or pipelines. Moreover, according to the signal requirements, it is possible to control to direct only cold air to a desired position or only direct hot air to a desired position. In a specific embodiment of the present invention, the cold air and the hot air can be separately directed to the frame 18. In addition, an exhaust gas outlet that is discharged outside the eyeglass body 1 is additionally provided. When the micro vortex tube 3 receives a signal to cool the nose pad 2, the cold air generated by the micro vortex tube 3 is directed toward the demand gas outlet 39 of the lens frame 18, and the generated hot air leaves the glasses body 1 from the exhaust gas outlet; or when the micro vortex When the tube 3 receives the signal requesting the nose pad 2 to heat up, the hot air generated by the micro vortex tube 3 is directed to the required gas outlet 39 of the lens frame 18, and the generated cold air leaves the spectacle body 1 from the exhaust gas outlet.

In a specific embodiment, the frame 18 includes a heat pipe 19 for coupling the nose pad 2 and the micro vortex tube 3 respectively. The micro vortex tube 3 lowers the temperature of the nose pad 2 or raises the temperature through the heat pipe 19. In FIG. 1, the heat pipe 19 is shown in solid black. One end of the heat pipe 19 is provided at the outlet of the micro vortex tube 3, so the cold air or hot air discharged from the demand gas outlet 39 of the micro vortex tube 3 can blow the heat pipe 19. The hot gas then transfers the heat energy to the heat pipe 19, or the cold gas takes away the heat energy of the heat pipe 19. Therefore, the micro vortex tube 3 can selectively raise or lower the temperature of the heat transfer tube 19.

In a specific embodiment, the material of the heat pipe 19, the nose pad 2, or the components for coupling the heat pipe 19 and the nose pad 2 can be made of metal, ceramics, carbon fiber, silicone, or other materials with high thermal conductivity. In practical applications, the metal may be gold, silver, copper, aluminum, iron, nickel, or its related thermally conductive compound. By conducting heat quickly and efficiently with the heat pipe 19, the micro vortex tube 3 can change the temperature of the nose pad 2 in turn.

In another specific embodiment, the cold air and the hot air are not directed to the same gas outlet, but can be blown toward the heat pipe 19 respectively. When the micro vortex tube 3 receives a signal for cooling, the cold air generated by the micro vortex tube 3 blows from the cold air outlet 37 toward the heat pipe 19, and the generated hot air leaves the glasses body 1 from the exhaust gas outlet; otherwise, when the micro vortex tube 3 receives When a warming signal is required, the hot air generated by the micro vortex tube 3 is blown from the hot air outlet 38 toward the heat pipe 19, and the generated cold air leaves the eyeglass body 1 from the exhaust gas outlet.

In another specific embodiment, part of the cold air and part of the hot air produced by the micro vortex tube 3 simultaneously blow the heat pipe 19 to adjust the temperature of the heat pipe 19.

In a specific embodiment, the eyeglass body 1 of the smart glasses 100 includes two temples 11, each of which is provided with a micro vortex tube 3, and the heat transfer tube 19 of the frame 18 has multiple endpoints, of which two ends A micro vortex tube 3 coupled to two mirror legs 11 respectively. The smart glasses 100 further includes two nose pads 2, which are also coupled to the heat pipe 19 respectively.

In a specific embodiment, a first mirror-shaped micro vortex tube 3 blows cold air only to the heat pipe 19, and a second mirror-shaped micro vortex tube 3 blows hot air only to the heat pipe 19. According to the requirements of the signal to increase or decrease the temperature, only one micro vortex tube 3 is started at the same time to change the temperature of the heat transfer tube 19 and further change the temperature of the nose pad 2.

In another specific embodiment, the micro vortex tubes 3 of the two mirror legs 11 respectively blow the heat pipe 19 with cold air and hot air at the same time. The temperature on the heat pipe 19 achieves the heat balance between the cold air and the hot air, and then the heat pipe 19 guides the temperature to the two nose pads 2 respectively.

Please refer to Figure 1 and Figure 2. 2 is a functional block diagram of a specific embodiment of the smart glasses 100 according to the present invention. In all the functional block diagrams of the present invention, the dotted line represents a wired or wireless signal connection, the thin solid line represents a connection on a circuit, and the thick solid line represents a connection on thermal energy conduction.

In a specific embodiment, the smart glasses 100 further includes a communication module 12 disposed on the glasses body 1 and coupled to the micro vortex tube 3 for wirelessly connecting a portable device 4. The portable device 4 is provided with an ambient temperature module 14 for sensing the change of an ambient temperature. When the ambient temperature drops at a rate that exceeds a first temperature change, the ambient temperature module 14 sends out a cooling signal. In a specific embodiment, after the micro vortex tube 3 receives the cooling signal through the communication module 12, the micro vortex tube 3 causes the nose pad 2 to cool down at a second temperature change rate.

In a specific embodiment, the portable device 4 may be a smart phone, smart bracelet, smart earphone, smart watch, smart ring, smart underwear, smart footwear, or other senses that are convenient to carry, wear, and have a communication function测装置。 Test device. The communication module 12 can be provided at the frame 18 or the temple 11, and the communication method can be transmitted through wired or wireless. Wireless communication includes wireless compatibility certification (Wireless Fidelity, Wi-Fi), Bluetooth (Bluetooth) or near field communication (Near Field Communication, NFC) and other communication methods, and is not limited to the above examples.

Please refer to Figure 1 and Figure 3. FIG. 3 is a functional block diagram of another embodiment of the smart glasses 100 according to the present invention. In a specific embodiment, the smart glasses 100 further includes an ambient temperature module 14 disposed on the glasses body 1 and coupled to the micro vortex tube 3. The ambient temperature module 14 is used to sense the change of an ambient temperature. When the ambient temperature drops at a rate exceeding a first temperature change rate, the ambient temperature module 14 sends out a cooling signal. In a specific embodiment, after the micro-vortex tube 3 receives the cooling signal, the micro-vortex tube 3 cools the nose pad 2 at a second temperature change rate.

This specific embodiment has the same function as the temperature environment module 14 of the previous embodiment. The difference between the two embodiments is that the environment temperature module 14 is disposed on the eyeglass body 1 or the portable device 4. If the ambient temperature module 14 is disposed on the eyeglass body 1, the purpose of the invention can be achieved without additionally wearing a portable device 4. The environment temperature module 14 installed in the portable device 4 is suitable for users who need to wear the portable device 4, thereby reducing the weight of the glasses body 1 and achieving the purpose of the invention. The functions of the ambient temperature module 14 include continuously detecting the real-time temperature, calculating the temperature change within a period of time, and sending a signal to the micro vortex tube 3.

Please refer to Figure 1, Figure 2 and Figure 3. In a specific embodiment, when the ambient temperature rises above a first temperature change rate, the ambient temperature module 14 sends out a warming signal to control the micro vortex tube 3 so that the nose pad 2 raises the temperature at a second temperature change rate . In the present invention, the first temperature change rate can be regarded as a threshold value. When the ambient temperature module 14 detects that the temperature change exceeds this change rate, it will send out a signal to cause the micro vortex tube 3 to blow cold air or hot air to the heat pipe 19.

In a specific embodiment, when the ambient temperature module 14 detects a change in air temperature, it will drive the micro vortex tube 3 to quickly adjust the temperature of the nose pad 2 to the original temperature at a third temperature change rate. 2. The temperature change rate gradually increases or decreases the temperature.

In a specific embodiment, the first temperature change rate is between 0.1 degrees Celsius per second (0.1-10°C/sec). In a specific embodiment, the first temperature change rate is 0.2 degrees Celsius per second (0.2°C/sec). In another specific embodiment, the first temperature change rate is 0.3 degrees Celsius per second (0.3°C/sec). In a specific embodiment, the second temperature change rate is between 0.1 and 10 degrees Celsius per minute (0.1 and 10°C/min). In a specific embodiment, the second temperature change rate is 0.2 degrees Celsius per minute (0.2°C/min). In a specific embodiment, the third temperature change rate is 1 degree Celsius per second (1.0°C/sec)

In a specific embodiment, the first temperature change rate is 0.5 degrees Celsius per second (0.5°C/sec), and the second temperature change rate is 0.5 degrees Celsius per minute (0.5°C/min). When a user wears smart glasses 100 and walks into a cold room (10°C) from a room temperature (25°C), the temperature change rate detected by the ambient temperature module 14 on the glasses body 1 or the portable device 14 is 1.0 ℃/sec. Because the detected temperature change rate is greater than the threshold value of the first temperature change rate, the ambient temperature module 14 sends a signal to operate the micro vortex tube 3 to control the nose pad 2 to cool slowly at a cooling rate of 0.5°C/min.

In a specific embodiment, the first temperature change rate is 0.2 degrees Celsius per second (0.2°C/sec), and the second temperature change rate is 0.2 degrees Celsius per minute (0.2°C/min). When a user wears smart glasses 100 and walks into the room (24°C) from the outside (30°C), the temperature change rate detected by the ambient temperature module 14 on the glasses body 1 or the portable device 14 is 0.3°C/ sec. The detected temperature change rate is greater than the threshold value of the first temperature change rate, so the ambient temperature module 14 first drives the micro vortex tube 3 to operate, so that the nose pad 2 which may have been slightly cooled back to the heating rate of 1.0°C/sec 30℃. Next, the nose pad 2 was slowly cooled to 24°C at a cooling rate of 0.2°C/min.

In a specific embodiment, the first temperature change rate is 0.1 degrees Celsius per second (0.1°C/sec), and the second temperature change rate is 1.0 degrees Celsius per minute (1.0°C/min). When a user wears smart glasses 100 and walks indoors (20°C) from outside (10°C), the temperature change rate detected by the ambient temperature module 14 on the glasses body 1 or the portable device 14 is 0.2°C/ sec. The detected temperature change rate is greater than the threshold value of the first temperature change rate, so the ambient temperature module 14 first drives the micro vortex tube 3 to operate, so that the nose pad 2 which may have been slightly heated back to the cooling rate of 1.0°C/sec 10℃. Next, the nose pad 2 was gradually heated up to 20°C at a heating rate of 1.0°C/min.

In a specific embodiment, the temperature rise and temperature drop detected by the ambient temperature module 14 may have different thresholds for the first temperature change rate. For example, when a temperature decrease is detected, the ambient temperature module 14 determines whether the first temperature change rate based on the signal is 0.2 degrees Celsius per second (0.2 ℃/sec); but when a temperature increase is detected, the ambient temperature module 14 determines The first temperature change rate based on whether the signal is sent is 1.0 degree Celsius per second (1.0°C/sec).

It can be known from the above embodiment that the ambient temperature module 14 detects the change of the ambient temperature in real time and generates a corresponding signal to the micro vortex tube 3. Then, the micro vortex tube 3 is activated according to the signal, and outputs a temperature gas corresponding to the signal to blow the heat pipe 19. Finally, through the heat conduction of the heat pipe 19, the temperature of the nose pad 2 is raised or lowered relatively slowly. Therefore, it can alleviate the discomfort that the severe temperature difference stimulates the nose when the user moves in an environment with different temperatures. In the above embodiment, when the nose pad 2 has reached the target temperature, the micro vortex tube 3 can stop working, so that the nose pad 2 and the ambient temperature reach thermal equilibrium.

Since the sensitivity of the nose of each user is different from the habit of using glasses, each has a suitable temperature change threshold and a time difference to adapt to the new temperature. Therefore, the values of the first temperature change rate, the second temperature change rate, and the third temperature change rate of the present invention only show the commonly used temperature change rate, but the actual value is not limited to the embodiments of the present invention.

Please refer to Figure 1, Figure 2 and Figure 4. FIG. 4 is a functional block diagram of an embodiment of a method for controlling the micro vortex tube 3 according to the present invention. In a specific embodiment, the smart glasses 100 further includes a nose pad temperature module 13 coupled to the micro vortex tube 3 for sensing the temperature of the nose pad 2 or the heat pipe 19, and then sends a signal to control the micro vortex tube 3 to adjust Work efficiency. In a specific embodiment, the nose pad temperature module 13 monitors that the temperature of the nose pad 2 or the heat pipe 19 is not lower than 15°C. Therefore, if the ambient temperature is 10°C and the nose pad 2 continues to cool down, the micro vortex tube 3 will first cool down to 15°C at the second temperature change rate, and then continue to work to maintain the nose pad 2 at least at 15°C, rather than Nose pad 2 drops to 10°C. Similarly, it can be seen that the ambient temperature module 14 or the nose pad temperature module 13 can also continuously control that the nose pad 2 is not lower than or higher than any temperature, and is not limited to the above 15°C.

In a specific embodiment, the smart glasses 100 further includes a humidity sensing module 15 disposed on the glasses body 1 and electrically coupled to the micro vortex tube 3, or disposed on the portable device 4 and connected to the micro via the communication module 12 Vortex tube 3. When the humidity sensing module 15 detects a change in ambient humidity, the humidity sensing module 15 controls the micro vortex tube 3 to lower or raise the temperature of the nose pad 2 within a period of time.

Patients with rhinitis are prone to suffer severe temperature differences and affect their noses when they get out of bed. In a specific embodiment, the smart glasses 100 is further provided with a vibration module 16 on the glasses body 1 and coupled to the micro vortex tube 3, or the portable device 4 is connected to the micro vortex tube 3 through the communication module 12. When the vibration module 16 detects vibration, the vibration module 16 sends a signal to the ambient temperature module 14, and then the ambient temperature module 14 drives the micro vortex tube 3 so that the nose pad 2 raises the temperature at a third temperature change rate. The user wears the portable device 4 or the glasses body 1 when sleeping, or wears the portable device 4 or the glasses body 1 when getting up. When the user gets up, the vibration module 16 senses vibration and sends a signal to the ambient temperature module 14. The ambient temperature module 14 sends a signal according to the ambient temperature, so that the micro vortex tube 3 is raised to an appropriate temperature at a third temperature change rate, for example, raised to 30°C at a rate of 1.0°C/sec. Then, it is reduced to the ambient temperature at the second temperature change rate, for example, to 20°C at a rate of 1.0°C/min.

In a specific embodiment, the smart glasses 100 is further provided with a body temperature module 17 coupled to the micro vortex tube 3. When the body temperature module 17 detects the body temperature, the body temperature module 17 sends a signal to the ambient temperature module 14. Then, the ambient temperature module 14 drives the micro vortex tube 3 so that the nose pad 2 raises the temperature at a third temperature change rate. The body temperature module 17 may have an infrared sensor to detect body temperature. When the user gets up and wears the smart glasses 100, the body temperature module 17 detects the body temperature and sends a signal to the ambient temperature module 14. The ambient temperature module 14 sends a signal according to the ambient temperature, so that the micro vortex tube 3 is raised to an appropriate temperature at a third temperature change rate, for example, raised to 35°C at a rate of 2.0°C/sec. Then, the temperature is reduced to ambient temperature at a second rate of temperature change, for example, to 22°C at a rate of 0.8°C/min.

With the arrangement of the vibration module 16 and the human body temperature module 17 in the above embodiment, the user wears the smart glasses 100 after getting up, and the nose pads 2 of the smart glasses 100 are heated in real time to avoid the nose caused by the severe temperature difference Uncomfortable. In practical applications, each module in FIG. 4 can also transmit signals to the micro vortex tube 3 without driving the signal to the ambient temperature module 14, so as to drive the micro vortex tube 3.

In a specific embodiment, the smart glasses 100 need not sense the ambient temperature with the ambient temperature module 14. The micro vortex tube 3 works intermittently to maintain the nose pad 2 in a temperature range. For example, every five minutes, the micro vortex tube 3 works for one minute to generate 25°C gas to blow the heat pipe.

In a specific embodiment, the glasses body 1 is further provided with a rechargeable battery and an external power socket. The rechargeable battery is coupled to the micro vortex tube 3 for power supply, and the external power socket is coupled to the rechargeable battery to charge the rechargeable battery from an external power source. The rechargeable battery may be a lithium battery. The external power socket can be a USB, micro-B, or Type-C interface.

Please refer to Figure 1 and Figure 5. FIG. 5 is a schematic diagram of another embodiment of the smart glasses 100 according to the present invention. In a specific embodiment, the glasses body 1 is vision correction glasses, modeling glasses, sunglasses, 3D glasses, virtual reality glasses, goggles, work goggles, diving goggles, wind goggles or ski goggles. Even if the nose of some patients with rhinitis is not directly exposed to cold air, it may still cause nasal discomfort due to the cooling of the body. As shown in FIG. 5, the spectacle body 1 is a diving goggles, and the micro vortex tube 3 is provided and embedded in the lens frame 18. The nose pad 2 is hidden in a nasal mask covering the nose. At this time, the nose pad 2 may also be in the shape of completely or partially covering the nose. The heat pipe 19 is also hidden in the frame 18 and extends into the nasal mask to connect the nose pad 2. When the user wears the goggles and launches the water, the micro vortex tube 3 is activated, and the nose pad 2 is continuously heated to maintain a fixed temperature, for example, 35°C. In this way, the user wearing the goggles can relieve the discomfort of the nose caused by the low water temperature.

Similarly, it can be seen that the micro vortex tube 3 can be disposed at the mirror frame 18. This arrangement is suitable for the glasses body 1 with a large frame, or for the glasses body 1 where the temple 11 is not easy to configure the micro vortex tube 3. In a specific embodiment, the nose pad 2 and the micro vortex tube 3 can also be installed in facial equipment such as a mask and a face mask, and can also relieve the nasal discomfort caused by the temperature difference.

Compared with the conventional technology, the smart glasses of the present invention can selectively change the temperature of the nose pads to prevent excessive temperature changes from irritating the nose and alleviating the symptoms of the nose of patients with rhinitis. The arrangement of the heat pipe enables the cold air and hot air produced by the micro vortex tube to communicate with the nose pads in the form of thermal energy to achieve efficient temperature conduction. The ambient temperature module continuously detects the ambient temperature and sends a temperature signal to the micro vortex tube when the temperature changes rapidly, so that the micro vortex tube changes the temperature of the nose pad at a relatively slow rate. Use the rest of the sensing modules to send signals to the ambient temperature module to adjust the temperature of the nose pads in real time and accurately under various conditions.

With the above detailed description of the preferred embodiments, it is hoped that the features and spirit of the present invention can be described more clearly, rather than limiting the scope of the present invention with the preferred embodiments disclosed above. On the contrary, the purpose is to cover various changes and equivalent arrangements within the scope of the patent application of the present invention. Therefore, the scope of the patent application scope of the present invention should be interpreted broadly based on the above description, so that it covers all possible changes and equivalent arrangements.

100‧‧‧Smart Glasses

1‧‧‧ glasses body

11‧‧‧Mirror feet

18‧‧‧Frame

19‧‧‧Heat pipe

2‧‧‧ nose pads

3‧‧‧mini vortex tube

30‧‧‧Gas inlet

33‧‧‧ vortex chamber

37‧‧‧cool air outlet

38‧‧‧Hot gas outlet

39‧‧‧ gas outlet

Claims (10)

An intelligent spectacles includes: a spectacle body; a nose pad, which is arranged on the spectacle body; and a micro vortex tube, which is arranged on the spectacle body and is coupled to the nose pad, and the micro vortex tube selectively makes the nose pad Lower the temperature or increase the temperature. The smart glasses as described in item 1 of the patent application scope, wherein the glasses body includes a frame and a temple, the nose pad is disposed on the frame, the micro vortex tube is disposed on the temple, and the frames are respectively coupled to the Nose pad and the micro vortex tube. The smart glasses as described in item 2 of the patent application scope, wherein the frame includes a heat pipe for coupling the nose pad and the micro vortex tube respectively, and the micro vortex tube reduces the temperature of the nose pad by the heat pipe Or raise the temperature. The smart glasses as described in item 1 of the patent application further includes a communication module disposed on the glasses body and coupled to the micro vortex tube for wirelessly connecting a portable device, wherein the portable device is provided with a The ambient temperature module is used to sense the change of an ambient temperature; when the ambient temperature drops at a rate that exceeds a first temperature change rate, the ambient temperature module sends a cooling signal. The smart glasses as described in item 1 of the patent application scope further includes an ambient temperature module, which is disposed on the glasses body and is coupled to the micro vortex tube. The ambient temperature module is used to sense a change in ambient temperature; When the ambient temperature drops at a rate that exceeds a first temperature change, the ambient temperature module sends a cooling signal. The smart glasses as described in item 4 or 5 of the patent application scope, wherein after the micro vortex tube receives the cooling signal, the micro vortex tube cools the nose pad at a second temperature change rate. The smart glasses as described in item 6 of the patent application range, wherein the first temperature change rate is greater than the second temperature change rate. The smart glasses as described in item 6 of the patent application scope, wherein when the ambient temperature rises at a rate that exceeds the first temperature change rate, the ambient temperature module sends out a warming signal to control the micro vortex tube to make the nose pad The temperature is increased at this second temperature change rate. Smart glasses as described in item 1 of the patent application scope, where the glasses system is vision correction glasses, modeling glasses, sunglasses, 3D glasses, virtual reality glasses, goggles, working goggles, diving goggles, wind goggles or skis mirror. The smart glasses as described in item 1 of the patent application scope, wherein the material of the nose pad includes at least one of metal, ceramics, carbon fiber and silicone.

Images