RU208178U1 - A device for identifying people with an increased body temperature - Google Patents

Abstract

The utility model relates to the field of measurement technology and can be used to remotely measure the temperature of an object using infrared (IR) radiation. The device for detecting people with elevated body temperature contains measuring units for data collection, a processed data output unit, a memory unit and a data processing and control module connected to them, each of the measuring units includes a parabolic reflector with a mirror surface, infrared sensors, located at its focus and equipped with NTC thermistors, and two ToF sensors to determine the distance from the device to the person. The use of the proposed solution improves the accuracy of non-contact measurement of people's temperature by a device whose measuring unit is equipped with a parabolic reflector with a mirror surface for focusing radiation on IR sensors. 6 w.p. f-ly, 2 ill.

Description

The utility model relates to the field of measuring technology, namely to means of remote measurement of the temperature of a human body by measuring infrared (IR) radiation, and can be used to identify people with elevated temperatures at the entrances to places of mass use.

A device for detecting people with an elevated body temperature (JP H04128684 A, 30.04.1992) is known from the prior art, containing a measuring unit made in a housing for collecting data on the temperature of a person's body and ambient air, including a parabolic reflector with a mirror surface, an IR sensor, located in its focus, and an NTC thermistor. The device also contains a processed data output unit and a data processing and control module associated with the said units, configured to calculate a person's temperature. The NTC thermistor calculates the ambient temperature, which is compared with the measured temperature of the human body. If the difference in measurements is higher than the set value, then there is a person in front of the device, and the measurement temperature is accepted.

This device is selected as a prototype. Its disadvantages are the low accuracy of temperature measurement, the lack of correction of the measured temperature of a person to the distance to him and to the temperature of the surrounding air, as well as the inability to automatically compare the measured values of temperatures with control values.

The task of the utility model is to create a device for detecting people with elevated body temperature, the measuring unit of which is equipped with a parabolic reflector with a mirror surface, devoid of the above disadvantages.

The technical result consists in the possibility of higher accuracy of non-contact measurement of the temperature of people with a device, the measuring unit of which is equipped with a parabolic reflector with a mirror surface for focusing radiation on IR sensors.

The specified result is achieved by a device for detecting people with an elevated body temperature, containing a measuring unit for collecting data made in a housing, a processing data output unit and a data processing and control module connected to them, due to the fact that it contains a unit connected to the data processing and control module memory and at least one additional measuring unit, and each of the measuring units includes a parabolic reflector with a mirror surface, IR sensors located in the focus of the reflector and equipped with NTC thermistors, and two ToF sensors for determining the distance from the device to a person, the housing is a vertical modular design, the measuring units are located one above the other.

The device contains from two to ten measuring units.

Also, each measuring unit of the device contains from three to eight IR sensors.

The parabolic reflector can be made of stainless steel, polished to a mirror finish.

The parabolic reflector can be made of stainless steel coated with mirror amalgam.

The output block contains modules of indication and sound notification.

The output block contains RS232, RS485, CAN and Ethernet data output ports.

The data processing and control module, coupled with NTC thermistors for determining the ambient temperature and with two ToF (Time of Flight) sensors for determining the distance to a person, provides increased accuracy of non-contact temperature measurement of people due to the possibility of correcting for ambient temperature and distance to the person.

The utility model is illustrated using Figs. 1-2.

Figures 1a-1b show drawings of a device for detecting people with elevated body temperature with two measuring units, front view and side view.

Figure 2 shows a diagram of the operation and the structure of the measuring unit.

A device for detecting people with an elevated body temperature (Figs. 1a-1b) contains two to ten measuring units 2 combined by a housing 1 for collecting data on a person's temperature, distance to him and the surrounding air, an output unit 3 of processed data, a memory unit (not shown) for storing processed data for the purpose of further analysis of the collected statistics and for storing temperature threshold values, for example + 37 ° C and + 38 ° C, and a data processing and control module (not shown) connected to the listed elements.

The housing 1 is a vertical modular structure with the arrangement of the measuring units 2 one above the other to provide the possibility of detecting infrared radiation, taking into account different growth groups of measurement objects, which contributes to an increase in the measurement accuracy. Modular design means the ability to connect the measuring units 2 to each other. Thus, a new unit 2 can be connected to the existing lower unit 2, to which, in turn, another unit 2 can be connected, and so on by means of known connections. The body 1 of the proposed device is not floor-standing and is installed on a support or suspended at a height that is selected taking into account the number of blocks 2 and growth groups of measurement objects.

Each measuring unit 2 contains two ToF 4 sensors for determining the distance to the measurement object - a person, a parabolic reflector 5, which can be made of stainless steel, polished to a mirror state or covered with mirror amalgam, from three to eight sensitive digital or analog IR sensors 6 with a viewing angle of up to 90 °, located in the focus of the reflector and carrying out detection of thermal radiation, while each IR sensor 6 is equipped with an NTC thermistor to determine the ambient temperature. IR sensors 6 with NTC thermistors and ToF sensors 4 are connected to the data processing and control module.

The number of measuring units 2 depends on the nature of the measurement object, for example, in educational institutions where students are students and adults, teachers, it is recommended to use from four to six measuring units 2 to cover the measurement area from 600 mm to 900 mm in height. In offices or enterprises with adult staff - from two to four blocks 2 for an area from 125 mm to 600 mm. It is possible to use more blocks 2.

The number of IR sensors 6 used also depends on the nature of the object on which the device will be installed. Three to five sensors are used in office premises with ambient temperatures ranging from + 20 ° С to + 26 ° С; from six to eight sensors are used on complex objects - checkpoints with possible drafts and temperature fluctuations from + 10 ° С to + 35 ° С, as well as at ambient temperatures close to the measured temperature of the human body from + 30 ° С to +39 ° C.

The data processing and control module is at least one processor, for example, a 32-bit processor, which carries out the functions of device control, collection and processing of data coming from the measuring units 2 to calculate the temperature of the human body taking into account the ambient temperature and distance from the measuring device, comparison calculated - measured - temperature with threshold values programmed in the memory block, counting the number of people whose temperatures were measured, for example, with grouping by temperature threshold values, and transferring the calculation results - processed data - to output block 3. Grouping can be done as follows: up to + 37 ° С - people with a normal body temperature, from + 37 ° to + 38 ° С - people with a threshold temperature value that requires attention, and more than + 38 ° С - people with a dangerously high temperature. The data processing and control module is implemented by means and methods known and obvious to a person skilled in the art.

The output unit 3 preferably includes a visual display module, for example one or more displays, an audible warning device and / or RS232, RS485, CAN and Ethernet data output ports for connection to external devices and monitoring systems. For example, the block for outputting processed data 3 can be implemented using one or more means:

segment digital indicator of red color, displaying the current digital values of the measurement results;

auxiliary LCD (LCD) -indicator for displaying service information (settings menu, values of ambient temperatures, values of the total number of measurements, etc.);

LED indicator providing color display taking into account the degree of danger;

an audible buzzer emitting an intermittent signal;

an mp3 player playing the corresponding audio fragment.

Thus, the data processing and control module is able to send signals to the output of the calculation results both with the help of visual and / or sound accompaniment, and, for example, in the access control system (ACS) of the enterprise. At the same time, to synchronize data with the ACS, the proposed device must be equipped with a real time clock (RTC) connected to the data processing and control module.

The proposed device works as follows.

The infrared radiation of a person passing by a device for detecting people with elevated body temperature falls into the field of view of one or more measuring units 2. Such a field of view of unit 2 is a cylinder, for example, 125 mm in diameter. IR radiation with the help of one or more mirror parabolic reflectors 5 is captured and focused on IR sensors 6, of which there can be from three to eight for each reflector 1 of unit 2. Due to the larger number of measuring units 2, the detected radiation of the object increases, which increases the accuracy measurements, as well as the fault tolerance of the device. IR sensors 6 convert the captured radiation into electrical signals forwarded to the data processing and control module. In parallel, the signals to the module are transmitted by an NTC thermistor built into each IR sensor 6 to compensate for the measurement results taking into account the ambient temperature, and two ToF 4 sensors, which provide sufficient accuracy in measuring the distance to a person with an error of no more than 5 mm due to the possibility of calculating and taking into account the average value of the distance between the readings of the two sensors.

The data processing and control module receives the measured values of the human temperature from each measuring unit 2 and receives for further processing those temperature readings that have the maximum value. For example, when using four blocks 2 and finding a person's face opposite the first upper block 2, the lower measuring blocks 2 actually measure the temperature of the clothes, which is usually up to + 25 ° C, and the upper block 2 measures the temperature of the face (neck, forehead) , which is in the range from + 32 ° С to + 40 ° С, and the data processing and control module, accordingly, builds its calculations on the data of the upper block 2.

The algorithm for making corrections to the values of the measured human temperature depending on the air temperature values from the NTC thermistor is a selection of the air and human temperature-dependent correction factor from the database provided by the manufacturer of analog or digital IR sensors 6 and stored in the memory unit, and adding the obtained coefficient into the results of calculations for further data output.

ToF sensors 4 work by tracking the distance between the emitter and the object based on a constant speed of light. Each ToF 4 sensor emits an array of light and tracks each pulse individually to create a depth map. This data is updated with a high sensing frequency, which allows accurate three-dimensional tracking of the object in front of the temperature measuring device in real time and, accordingly, corrects the measurement results depending on the distance of the object from the device.

The algorithm for making corrections to the measured temperature values depending on the values of the distance between the person and the measuring device is the calculation and accounting of the average value of the distance between the readings of two ToF sensors 4 located opposite the reflector 5, the selection of a correction factor from the base based on the measured values of the distance and temperature of the person data obtained empirically at the production stage for each manufactured device and stored in a memory unit, and adding the obtained coefficient to the calculation results for data output.

Thus, each temperature measurement consists in calculating the actual temperature of the human body by changing the measured values received from the IR sensors by multiplying them by the corresponding correction factors that the central processor selects from the databases stored in the memory unit. The implementation of the described algorithm of work is obvious to a person skilled in the art.

The data processing and control module, after calculating the actual temperature of the human body, compares it with the programmed threshold values stored in the memory unit. As a rule, these are values in the range from + 36 ° С to + 39 ° С, for example, + 37 ° С and + 38 ° С. And depending on the calculated body temperature value, corresponding information is output by the processed data output unit 3. For example, if the measured body temperature is up to + 37 ° C, then this corresponds to the normal level, the green indicator is automatically turned on; if the temperature is in the range from + 37 ° С to + 38 ° С, then this corresponds to the threshold value - the yellow indicator is automatically turned on; if the temperature is more than + 38C, then this corresponds to a critical level, the red indicator is automatically turned on, and a buzzer or audio fragment sounds. In an advantageous embodiment, the device always displays the calculated temperature of the object and the ambient temperature on a digital display.

Below are examples of the implementation of devices for detecting people with high body temperature.

1.32-bit processor for data processing, two measuring units with mirror-polished stainless steel reflectors, 125 mm in diameter, three digital IR sensors located in the focus of each reflector, NTC thermistor in each IR sensor and two ToF-sensors for each reflector.

The body is made vertical, the measuring units are located one above the other. Data from the processor goes to a sign indicator displaying the current digital values of the measurement results, a LED indicator that provides a color display of the degree of danger, an audible buzzer for emitting an intermittent signal, an mp3 player for playing the corresponding audio fragment and into the enterprise's ACS via one RS232, RS485 ports, CAN and Ethernet at the same time.

The device has an increased accuracy in determining the temperature of the human body with a device, the measuring unit of which is equipped with a parabolic reflector with a mirror surface for focusing radiation on IR sensors, due to corrections for the ambient temperature and distance to the measurement object, as well as due to two measuring units.

2.32-bit processor for data processing, ten measuring units with reflectors made of stainless steel coated with mirror amalgam and 125 mm in diameter, eight digital IR sensors located in the focus of each reflector, NTC thermistor in each IR sensor and two ToF sensors for each reflector.

The body is made vertical, the measuring units are located one above the other. Data from the processor enter a sign indicator displaying the current digital values of the measurement results, an LED indicator providing color display of the degree of danger, an audible buzzer for emitting an intermittent signal, an mp3 player for playing the corresponding audio fragment.

The device has an increased accuracy in determining the temperature of the human body with a device, the measuring unit of which is equipped with a parabolic reflector with a mirror surface for focusing radiation on IR sensors due to corrections for the ambient temperature and distance to the measurement object, as well as due to ten measuring units covering height maximum body surface area.

Thus, when using the proposed solution, the possibility of higher accuracy of non-contact measurement of the temperature of people is manifested by a device, the measuring unit of which is equipped with a parabolic reflector with a mirror surface for focusing radiation on IR sensors. In addition to this, the device has the ability to collect, store and accumulate data on the measurement of temperatures free from clothing areas of human bodies, and also has the function of interacting with the ACS and other automation tools at the entrance groups of objects of mass presence of people.

Claims (7)

1. A device for detecting people with elevated body temperature, containing a measuring unit for collecting data made in a housing, a processing data output unit and a data processing and control module connected to them, characterized in that it contains a memory unit connected to the data processing and control module and at least one additional measuring unit, each of the measuring units includes a parabolic reflector with a mirror surface, infrared sensors located in the focus of the reflector and equipped with NTC thermistors, and two ToF sensors for determining the distance from the device to a person, the housing is a vertical modular structure, the measuring units are located one above the other. 2. The device according to claim 1, characterized in that it contains from two to ten measuring units. 3. The device according to claim 1, characterized in that each measuring unit contains from three to eight infrared sensors. 4. The device according to claim 1, characterized in that the parabolic reflector is made of stainless steel, polished to a mirror-like state. 5. The device according to claim 1, characterized in that the parabolic reflector is made of stainless steel coated with mirror amalgam. 6. The device according to claim 1, characterized in that the output unit contains indication and sound notification modules. 7. The device according to claim 5, wherein the output unit contains data output ports RS232, RS485, CAN and Ethernet.

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