CN111238656B

CN111238656B - Temperature measurement glasses and temperature measurement method thereof

Info

Publication number: CN111238656B
Application number: CN202010217716.2A
Authority: CN
Inventors: 刘娟
Original assignee: Changzhou Vocational Institute of Textile and Garment
Current assignee: Changzhou Vocational Institute of Textile and Garment
Priority date: 2020-03-25
Filing date: 2020-03-25
Publication date: 2021-06-18
Anticipated expiration: 2040-03-25
Also published as: CN111238656A

Abstract

The invention provides temperature measurement glasses and a temperature measurement method thereof, wherein the temperature measurement glasses comprise a glasses frame, a temperature measurement module and a control module, the temperature measurement module and the control module are installed on the glasses frame, the glasses frame comprises glasses legs, the temperature measurement module and the control module are both installed on the glasses legs, and the temperature measurement method comprises the following steps: step S1: starting a temperature measurement module and a control module, wherein the temperature measurement module collects infrared rays emitted by the forehead of people around; step S2: the infrared ray with the temperature of 37-40 ℃ can drive the infrared temperature measurement sensor to start, and the infrared temperature measurement sensor can transmit an electric signal to the control module according to the received infrared ray intensity; step S3: the control module sends a data signal to the mobile terminal according to the strength of the electric signal; step S4: the mobile terminal analyzes the data signals and reminds users of keeping away from the flu personnel, and the flu personnel can be actively avoided by using the temperature measurement glasses and the temperature measurement method, so that the flu infection range can be prevented from being enlarged, and the safety of the personnel can be ensured.

Description

Temperature measurement glasses and temperature measurement method thereof

Technical Field

The invention relates to the technical field of body temperature detection, in particular to temperature measurement glasses and a temperature measurement method thereof.

Background

After influenza occurs, in order to prevent large-area infection of influenza, people who suffer from fever in people often need to be far away, when people who suffer from fever in people are screened, a non-contact temperature measurement method is often adopted for body temperature detection, the traditional questioning detection adopts two modes of a temperature measurement gun or a temperature measurement camera, when the temperature measurement gun is used, the temperature measurement gun needs to keep a certain specified distance from the detected people and needs to be aligned with the forehead and other parts of a human body, when the temperature measurement camera is used, the temperature measurement camera needs to be installed at a certain specified position, the temperature measurement camera carries out infrared imaging and color imaging on the passing people and is matched with a face identification technology to carry out temperature measurement on the face of the passing people, and further the equipment is large in size and difficult to carry, so when the two technical means are applied, the body temperature detection cannot be conveniently carried out on nearby people, that is, nearby fever sufferers cannot be screened out in real time.

Thus, the patent number: CN2857050 discloses a can detect glasses of human temperature all around, specifically discloses install infrared temperature detector probe on glasses to set up the technical scheme of LCD display screen in the lens upper corner, above-mentioned technical scheme when using, needs the person of carrying to adjust the direction of detector probe, and aim at the time of being detected personnel 3 seconds to 5 seconds, can show being detected personnel's body temperature on LCD display screen. In the whole temperature measurement process, the glasses can only detect a single specified target, namely a detection object is specified by a carrying person, and large-area body temperature detection cannot be performed on nearby people.

Disclosure of Invention

The invention provides temperature measurement glasses capable of carrying out large-area body temperature detection on nearby people.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides a temperature measurement glasses, includes the spectacle frame and installs temperature measurement module and control module on the spectacle frame, the spectacle frame includes the mirror leg, temperature measurement module and control module all installs on the mirror leg, temperature measurement module is including detecting lens and infrared temperature sensor, it installs to detect the lens on the mirror leg, infrared temperature sensor corresponds detecting lens installs on the mirror leg, control module sets up keep away from on the mirror leg detecting lens, control module with be the electricity between the infrared temperature sensor and connect, control module can be according to infrared temperature sensor's the detection condition sends data signal.

Furthermore, the spectacle frame further comprises spectacle frames, the spectacle legs are respectively arranged on two sides of the spectacle frame, and the temperature measuring module and the control module are respectively arranged on the two spectacle legs.

Furthermore, the detection lens and the infrared temperature sensor are both installed at the end part, close to the mirror bracket, of the mirror leg, the detection lens extends upwards for 1 cm-2 cm, and the control module is far away from the infrared temperature sensor and is arranged on the mirror leg.

Furthermore, the control module comprises a receiving unit, a processing unit and a transmission unit, the receiving unit is electrically connected with the infrared temperature measuring sensor, the receiving unit receives the electric signal of the infrared temperature measuring sensor, the processing unit analyzes the electric signal, and the transmission unit sends out a corresponding data signal to the mobile terminal according to the analysis result.

Further, the invention also provides a temperature measuring method applied to any one of the temperature measuring glasses, and the temperature measuring method comprises the following steps:

step S1: starting a temperature measuring module and a control module, wherein the temperature measuring module collects infrared rays emitted by a heat source;

step S2: the infrared ray with the temperature of 37-40 ℃ can drive the infrared temperature measurement sensor to start, and the infrared temperature measurement sensor can transmit an electric signal to the control module according to the received infrared ray intensity;

step S3: the control module sends a data signal to the mobile terminal according to the intensity of the electric signal;

step S4: the mobile terminal analyzes the data signals and reminds users of keeping away from flu people.

Further, the step S3: the control module sends out a data signal to the mobile terminal according to the strength of the electric signal, and the control module further comprises: the receiving unit in the control module receives the electric signal, the processing unit analyzes the intensity of the electric signal, and the transmission unit sends out a corresponding data signal according to the intensity of the analyzed electric signal.

Further, the step S4: the mobile terminal analyzes the data signal, and further comprises: the mobile terminal compares the data signals, sets corresponding setting signals in the mobile terminal, compares the data signals according to the setting signals, and sends out early warning according to comparison results.

Further, the step S4: the mobile terminal analyzes the data signal, and further comprises: when the data signal is in accordance with the corresponding set signal at 37-37.5 ℃, comparing the subsequent 3 data signals again, wherein the early warning is sent out when the temperature of the two data signals is above 37.3 ℃, and the early warning is directly sent out when the temperature of the data signal is between 37.5-41 ℃.

The glasses have the advantages that the temperature measurement module and the control module for infrared temperature measurement are arranged on the glasses, when flu occurs, infrared rays emitted by a surrounding heat source are collected through the temperature measurement module, the control module is used for discriminating the temperature of the heat source until a suspected heat source occurs, the control module sends an early warning signal to a mobile terminal such as a mobile phone, the mobile terminal sends early warning information to a carrying person, and after the carrying person receives the early warning, the carrying person can judge whether the heat source is a human or not through observation and further judge whether the heat source is a fever person or not.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a perspective view of thermometric glasses according to the present invention;

FIG. 2 is a block diagram based on the thermometric glasses shown in FIG. 1;

FIG. 3 is a flow chart of a temperature measuring method of the temperature measuring glasses according to the present invention;

in the figure:

thermometric module 20 of thermometric glasses 100 and glasses frame 10

Control module 30 temple 110 frame 120

Receiving unit 310 processing unit 320 transmission unit 330

Infrared temperature measurement sensor 220 of temperature measurement method 200 detection lens 210

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention. On the contrary, the embodiments of the invention include all changes, modifications and equivalents coming within the spirit and terms of the claims appended hereto.

As shown in fig. 1 and 2, the present invention provides a pair of thermometric glasses 100, which includes a frame 10, a thermometric module 20 mounted on the frame 10, and a control module 30.

The spectacle frame 10 comprises a temple 110 and a frame 120, wherein the temple 110 is respectively arranged at two sides of the frame 120, and the temperature measuring module 20 and the control module 30 are respectively correspondingly arranged on the two temples 110.

The temperature measuring module 20 includes a detecting lens 210 and an infrared temperature measuring sensor 220 electrically connected to the detecting lens, preferably, the detecting lens 210 is a convex lens with a focal length of 1.5 m. An optical filter is attached to the mirror surface of the detection lens 210, and preferably, the optical filter is an infrared filter with a selectable wavelength of 9-13 ч m. The detection lens 210 is mounted on the temple 110, and the detection lens 210 preferably extends upward by 1cm to 2cm, it can be understood that the detection lens 210 attached with the optical filter has an effective infrared ray receiving range of 180 ° in a sector area bounded by the temple 110, the detection lens 210 can receive infrared rays radiated from the heat source on a semicircular area boundary having a diameter of 1.5m, and according to planck's law, the wavelength of the infrared rays radiated from the heat source is inversely proportional to the temperature of the heat source, that is, the higher the temperature of the heat source, the shorter the wavelength of the infrared rays, and in the present embodiment, the focal length of the detection lens 210 is preferably 1.5 m. The temperature of a heat source corresponding to the infrared ray with the wavelength of 9-13 ч m is 37-40 ℃. It can be understood that when the temperature of the heat source reaches 37 ℃ to 40 ℃, the wavelength of the infrared ray radiated by the heat source is 9 to 13 ч m after the infrared ray is transmitted by 1.5m, the infrared ray radiated by the heat source can be focused by the detection lens 210 and then projected onto the infrared temperature measurement sensor 220, and when the infrared ray reaches the detection threshold of the infrared temperature measurement sensor 220, a variable electrical signal can be sent to the control module 30, preferably, the detection threshold of the infrared temperature measurement sensor 220 is set to the infrared wavelength corresponding to 37.3 ℃, that is, the infrared wavelength corresponding to the detection threshold is adjusted to 12.5 ч m, and further, when the temperature of the heat source reaches 37.3 ℃ or above, the infrared temperature measurement sensor 220 can generate a corresponding electrical signal. Preferably, the infrared sensor is of the type: a heat sensitive sensor of OTP-538U.

The control module 30 is installed on the temple 110, the control module 30 is far away from the infrared temperature measuring sensor 220, further, the control module 30 is separately installed on the temple 110 at both sides of the frame 120, and the control module 30 is electrically connected with the temperature measuring module 20 at the same side. Specifically, the control module 30 includes a receiving unit 310, a processing unit 320 and a transmitting unit 330, the receiving unit 310 is electrically connected to the infrared temperature sensor 220, preferably, the temple 110 is in a hollow shaft structure, and the wires connecting the receiving unit 310 and the infrared temperature sensor 220 are all disposed in the inner cavity of the temple 110. The receiving unit 310 may receive the electrical signal of the infrared temperature measuring sensor 220, the processing unit 320 may analyze the intensity of the electrical signal, the transmission unit 330 may send out a corresponding data signal according to the analysis result of the processing unit 320, the data signal is transmitted to the mobile terminal such as a mobile phone through bluetooth or a data network, and further, the frequency bands of the data signal sent out by the transmission units 330 at the two sides of the lens frame 120 are different, that is, the data signal has a significance in a corresponding direction.

The power supply is further mounted on the glasses legs 110, preferably, the power supply is a button battery, the power supply is mounted at the tail end, far away from the glasses frame 120, of the glasses legs 110, the power supply is electrically connected to the infrared temperature measuring sensor 220 and the control module 30, a button switch is arranged on the power supply, and power can be supplied to the control module 30 and the infrared temperature measuring sensor 220 after the switch is turned on.

As shown in fig. 2 and fig. 3, the present invention further provides a temperature measuring method 200 based on the above temperature measuring glasses 100, wherein the temperature measuring method 200 includes the following steps:

step S1: and (3) starting a power supply, supplying power to the temperature measuring module 20 and the control module 30, collecting infrared rays at two sides of the human body by the detection lens 210, and projecting the infrared rays onto the infrared temperature measuring sensor 220.

Specifically, the focal length of the detection lens 210 is preferably 1.5m, that is, infrared rays emitted from a heat source on a semicircular fan-shaped boundary with a diameter of 1.5m, which is centered on the detection lens 210, can be projected onto the detection lens 210, and when the temperature of the heat source is 37 ℃ to 40 ℃, the emitted infrared rays can be projected onto the infrared temperature measurement sensor 220 after passing through the detection lens 210.

Step S2: the infrared temperature sensor 220 emits a corresponding electrical signal according to the received infrared wavelength.

Since the wavelength of the infrared ray is correspondingly changed along with the temperature of the heat source, specifically, the higher the temperature of the heat source is, the shorter the wavelength of the infrared ray is, when the infrared ray focused by the detection lens 210 reaches the threshold of the infrared temperature measurement sensor 220, the infrared temperature measurement sensor 220 is started, the threshold of the infrared temperature measurement sensor 220 can be adjusted according to the focal length of the convex lens, and the infrared intensity in the focal length can trigger the infrared temperature measurement sensor 220, further, the infrared ray emitted from the heat source outside the focal length can not reach the threshold of the infrared temperature measurement sensor 220 after being focused by the convex lens due to the light diffusion phenomenon, that is, a corresponding electrical signal is generated according to the wavelength of the infrared ray, that is, the higher the temperature of the heat source is, the shorter the wavelength of the infrared ray is, the higher the intensity of the electrical signal is, and the.

Step S3: the control module 30 sends a data signal to the mobile terminal according to the electrical signal.

Specifically, after the receiving unit 310 in the control module 30 receives the electrical signal of the infrared temperature measuring sensor 220, the processing unit 320 analyzes the strength of the electrical signal, when the strength of the electrical signal reaches the strength set in the processing unit 320, the transmitting unit 330 is controlled by the processing unit 320 to send a data signal, and the data signal sent by the transmitting unit 330 corresponds to the strength of the electrical signal received by the receiving unit 310.

More specifically, a threshold interval corresponding to the electric signal is set in the processing unit 320, the threshold interval corresponds to the heat source temperature, and preferably, the heat source temperature specifically corresponding to the threshold interval is 37.3 ℃ to 40 ℃. After the receiving unit 310 receives the electrical signal, the processing unit 320 compares the received electrical signal strength with the electrical signal strength within the threshold interval, and controls the transmission unit 330 to send out the data signal according to the overlapped electrical signal, preferably, the data signal adopts a progressive algorithm to control the strength, i.e., the higher the strength of the electrical signal is, the higher the strength of the data signal is. It can be understood that after the comparison processing in the above steps is performed, the electrical signal can be converted into a data signal, the data signal changes according to the intensity of the electrical signal, and then the transmission unit 330 can transmit the data signal to the mobile terminal through a data transmission means such as a mobile network or bluetooth.

Step S4: the mobile terminal analyzes the data signal and judges whether flu people appear or not according to the data signal.

Specifically, the mobile terminal may be a mobile phone, a notebook computer, or an intelligent bracelet, and the intelligent bracelet is preferred in this embodiment. Setting a corresponding analysis program in the mobile terminal, when the analysis program runs, firstly analyzing the source of the data signal, judging whether the frequency band of the data signal is in accordance with the transmission unit 330 on the left side or the right side of the human body, further comparing whether the temperature represented by the data signal is 37.3-37.5 ℃ after judging that the source of the data signal is the transmission unit 330 on the left side or the right side of the human body, if the data signal is in accordance with the range, comparing the subsequent 3 times of data signals again, if the two times of data signals are both above 37.3 ℃, sending out a corresponding left early warning or right early warning, and if the temperature represented by the data signal is between 37.5-40 ℃, directly sending out the left early warning or right early warning. Preferably, the early warning mode may be a vibration prompt or a voice broadcast prompt, and is not particularly limited in this embodiment.

When the temperature measuring glasses 100 and the temperature measuring method 200 are applied, a person carrying the temperature measuring glasses 100 can directly erect the temperature measuring glasses 100 on the bridge of the nose, and after the switch is turned on, the person can detect the heat source at the focus boundary of the detection lens 110, for example, in a dense area such as a station, a school, a community, etc., a human body away from the focus boundary of the temperature measuring glasses 100 is used as a black body, the emitted infrared rays are absorbed by the detection lens 110 and projected onto the infrared temperature measuring sensor 220, the infrared temperature measuring sensor 220 sends out corresponding electrical signals according to the wavelength of the infrared rays, the electrical signals are transmitted to the control module 30, the control module 30 outputs data signals to the mobile terminal according to the intensity of the electrical signals, analyzes the data signals through a program in the mobile terminal, and further judges whether the heat source belongs to a suspected heat source, and sends out an early warning, the carrying personnel who prompts temperature measurement glasses 100 keeps away from the heat source, and after the carrying personnel receives the early warning, whether the heat source is a human body can be observed, if the human body exists in 1.5m, the human body is kept away, so that the carrying personnel is prevented from contacting with the fever personnel, the possibility of cross infection is reduced, and if the heat source in 1.5m is not a human body, the position of the heat source is changed, and the phenomenon of error detection is prevented.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. A temperature measurement glasses is characterized in that: the glasses frame comprises glasses frames, a temperature measurement module and a control module, wherein the temperature measurement module and the control module are installed on the glasses frames, the temperature measurement module comprises a detection lens and an infrared temperature measurement sensor, the detection lens is installed on the glasses frames, the infrared temperature measurement sensor is installed on the glasses frames corresponding to the detection lens, the control module is arranged on the glasses frames and is far away from the detection lens, the control module is electrically connected with the infrared temperature measurement sensor, and the control module can send out data signals according to the detection condition of the infrared temperature measurement sensor;

the control module comprises a receiving unit, a processing unit and a transmission unit, the receiving unit is electrically connected with the infrared temperature measuring sensor, the receiving unit receives an electric signal of the infrared temperature measuring sensor, the processing unit analyzes the electric signal, and the transmission unit sends a corresponding data signal to the mobile terminal according to an analysis result;

the intensity of the electric signal is analyzed through the processing unit, when the intensity of the electric signal reaches the intensity set in the processing unit, the transmission unit is controlled by the processing unit to send out a data signal, and the data signal sent out by the transmission unit corresponds to the intensity of the electric signal received by the receiving unit.

2. The thermometric glasses according to claim 1, wherein: the glasses frame further comprises a glasses frame, the glasses legs are arranged on two sides of the glasses frame respectively, and the temperature measuring module and the control module are arranged on the two glasses legs respectively.

3. The thermometric glasses according to claim 2, wherein: the detection lens and the infrared temperature sensor are both installed at the end part, close to the mirror bracket, of the mirror leg, the detection lens extends upwards for 1 cm-2 cm, and the control module is far away from the infrared temperature sensor and is arranged on the mirror leg.

4. A temperature measuring method applied to any one of the temperature measuring glasses of claims 1 to 3, characterized in that: the temperature measuring method comprises the following steps:

5. The method of claim 4, wherein: the step S3: the control module sends out a data signal to the mobile terminal according to the strength of the electric signal, and the control module further comprises: the receiving unit in the control module receives the electric signal, the processing unit analyzes the intensity of the electric signal, and the transmission unit sends out a corresponding data signal according to the intensity of the analyzed electric signal.

6. The method of claim 4, wherein: the step S4: the mobile terminal analyzes the data signal, and further comprises: the mobile terminal compares the data signals, sets corresponding setting signals in the mobile terminal, compares the data signals according to the setting signals, and sends out early warning according to comparison results.

7. The method of claim 4, wherein: the step S4: the mobile terminal analyzes the data signal, and further comprises: when the data signal is in accordance with the corresponding set signal at 37-37.5 ℃, comparing the subsequent 3 times of data signals again, wherein the early warning is sent out when the temperature of two times is above 37.3 ℃.