RU226724U1 - Glycerin vapor and tobacco smoke detector - Google Patents

Abstract

The utility model relates to detectors designed to monitor the air condition for the presence of glycerin vapors and tobacco smoke in order to prevent the consumption of nicotine-containing products in places not intended for this, including the consumption of vapes and tobacco heating systems. The purpose of the utility model is to create a compact, structurally simple, lightweight device for capturing glycerin vapor and tobacco smoke, with a remote data transmission function. The technical result of the claimed utility model is to provide remote transmission of information about the presence of glycerin vapor and tobacco smoke. The technical result is achieved in that the glycerin vapor and tobacco smoke detector contains a housing, a power supply, an LED displaying operating modes and elements for attaching the housing to the surface, a highly sensitive infrared sensor, and the device contains a microcontroller with the ability to transmit data via a wireless protocol to external devices, The microcontroller is connected to at least one highly sensitive infrared sensor for the presence of vapors of harmful substances in the air, while the LED is connected to the digital output of the microcontroller. The microcontroller is connected to a highly sensitive infrared sensor for the presence of harmful vapors in the air via the I2C bus. The device body is made of plastic.

Description

The utility model relates to detectors designed to monitor the air condition for the presence of glycerin vapors and tobacco smoke in order to prevent the consumption of nicotine-containing products in places not intended for this, including the consumption of vapes and tobacco heating systems.

The “Universal Detector of Air Pollutants” is known (see RF utility model patent No. 166503, publ. 2016), containing a housing, a power supply, LEDs located on the housing to display operating modes, a high-bright LED light signaling and elements for mounting the housing on vertical surfaces , an alarm sound emitter located inside the housing, an electronic circuit that includes a highly sensitive semiconductor sensor with continuous health monitoring and a resistor for adjusting the sensitivity level of the sensor, additionally contains a button located on the housing to check the health of the sound and light alarm, a built-in timer made in the form of an electronic circuit and providing automatic switching from warm-up mode to operating mode and protection against false alarms when the supply voltage deviates, a voltage stabilizer that ensures operation from unstabilized voltage sources and when operating from the vehicle's power supply network.

However, the known device is not intended to capture glycerin vapors generated when using electronic cigarettes or vapes.

The purpose of the utility model is to create a compact, structurally simple, lightweight device for capturing glycerin vapor and tobacco smoke, with a remote data transmission function.

The technical result of the claimed utility model is the creation of a structurally simple device with the function of remote transmission of data on the presence of volatile organic compounds and carbon dioxide.

The technical result is achieved by the fact that the detector of volatile organic compounds and carbon dioxide contains a housing, a power source, an LED displaying operating modes and elements for attaching the housing to the surface, a highly sensitive sensor, a microcontroller is located inside the housing with the ability to transmit data via a wireless protocol to external devices, The microcontroller is connected to at least one highly sensitive sensor for the presence of total volatile organic compounds and carbon dioxide in the air, while the LED is connected to the digital output of the microcontroller, the housing is made of plastic with a hole for the LED and a hole for the highly sensitive sensor. The microcontroller is connected to a highly sensitive semiconductor sensor for the presence of total volatile organic compounds and carbon dioxide in the air via the I2C bus.

The proposed technical solution is illustrated by implementation examples, where Fig. 1 shows an example of an assembled device, Fig. Figure 2 shows the components of the device, where 1 is a plastic case with hole-2 for LED-3 and hole-4 for sensor -5 for the presence of vapors of harmful substances in the air, mountings-6 for sensor -5, microcontroller-7; fastenings-8 housings; hole 9 for connecting the device; Figure 3 is a diagram of the connection of components.

The device contains a plastic housing-1, see Fig.1. The body-1 of the device can be made of different types of plastic, such as PLA, PETG, ABS, PEEK, ABS CF, PP, ASA, PC/ABS.

Housing-1 (see Fig. 2) contains electronic components, such as microcontroller-7, for example, the WeMos D1 mini microcontroller for processing values obtained from sensor-5 for the presence of harmful vapors in the air (for example, CSS811 sensor), connected via I2C bus, LED-3, power wire (type C), power supply (for example, 5V, 1A).

Microcontroller-7 can be used with any of the ESP8266 and ESP32 line of microcontrollers. LED -3 can be used with any diameter of 3 mm and 5 mm.

An example of connecting components, see Fig.3.

1) Microcontroller-7 (WeMos D1 mini) to sensor-5 (CSS811)

3v3 - VCC (plus power)

G - GND (minus power)

D1 - SCL (data line)

D2 - SDA (data line)

G - WAKE (contact responsible for automatically sending data to the microcontroller)

2) Microcontroller-7 (WeMos D1 mini) to LED-3 (indicator)

G - cathode (-) (minus power)

D5 - anode (+) (power plus)

The device works as follows.

The operating principle of the device is based on the electrochemical method of detecting gases and other impurities in indoor air using highly sensitive semiconductor sensors.

The devices can be installed anywhere in the room (on walls, ceilings) where it is necessary to monitor the air condition.

The device can be connected via a Type-C connector or a Micro-USB connector.

When the device is turned on, LED-3 lights up, the device begins to connect to the Wi-Fi network (via TCP/IP protocol), if the device was able to connect, then LED-3 begins to blink (at a speed of 1 Hertz indicating that the connection was successful), after a successful connection to the Wi-Fi network, microcontroller-7 begins to receive data from sensor-5 about the state of the air (the amount of CO ₂ and the amount of volatile organic substances, propylene glycol vapor, information is received via the I2C interface from the CCS811 sensor).

After receiving the data, the device processes it using an algorithm. An example of how the algorithm works - the first value is taken from the sensor, a delay of 5 seconds occurs and the second value is taken from sensor-5, then the first value is subtracted from the second value, if the difference in values is less than -3, then it is concluded that smoking has occurred in the room.

If the concentration of substances increases in the room, the device sends the user a notification to a mobile device (using the HTTP protocol to servers, for example, Telegram, through which the notification is subsequently transmitted to the user’s device) connected to a Wi-Fi network with Internet access.

Then it waits for 2 minutes, and if it detects an excess again, it sends a notification again; if not, it continues to analyze the air condition.

The proposed device detects not only the amount of CO ₂ , but also propylene glycol vapor (vapor) and notifies the user remotely. Notification of people occurs, for example, through a specially created bot on the Telegram social network, the user receives a notification that contains the notification “smoking”, which may additionally contain information about the amount of CO ₂ (carbon dioxide).

The use of the claimed utility model makes it possible to learn about smoking and respond to it in a timely manner, preventing future repetitions of violations.

Claims (2)

1. A detector of volatile organic compounds and carbon dioxide, containing a housing, a power source, an LED displaying operating modes and elements for attaching the housing to the surface, a highly sensitive sensor, characterized in that a microcontroller is located inside the housing with the ability to transmit data via a wireless protocol to external devices, The microcontroller is connected to at least one highly sensitive sensor for the presence of total volatile organic compounds and carbon dioxide in the air, while the LED is connected to the digital output of the microcontroller, the housing is made of plastic with a hole for the LED and a hole for the highly sensitive sensor. 2. The detector of volatile organic compounds and carbon dioxide according to claim 1, characterized in that the microcontroller is connected to a highly sensitive semiconductor sensor for the presence of total content of volatile organic compounds and carbon dioxide in the air via the I2C bus.