A Cost-Effective IoT System for Monitoring Indoor Radon Gas Concentration
Abstract
:1. Introduction
- It is able to collect data from Commercial Off-The-Shelf (COTS) radon sensors and transmit them to a central server where they can be stored and processed.
- It offers a remote user-friendly web interface that shows the current and historic series of the radon concentration values.
- The system can be configured to set alert thresholds and sampling frequencies to react to abnormal radon gas concentrations.
- It is able to send remote alerts to the subscribed users to warn them about exceeding radon concentration levels.
- It can activate mitigation devices (e.g., forced ventilation) to decrease radon gas concentration.
2. Related Work
2.1. Types of Radon Detection Devices
- Sensors based on electret ion chambers: These are passive devices that act as integrating detectors that estimate the average radon gas concentration [34]. Such devices have shown excellent accuracy, but standard operation procedures must be followed to avoid interference from background gamma radiation [35] or the presence of dust in the electrets [36].
- Solid-state silicon detectors: Most electronic integrating devices are able to count the alpha particles emitted by radon and its decay products by making use of a solid-state silicon detector and a diffusion chamber. These devices have two main restrictions. First, they usually require long integration periods (more than two days), because of the small dimensions of their diffusion chambers. Second, their measurements can be altered in high humidity environments [37].
- Scintillation cells and current or pulse ionization chambers: These are mainly used for building continuous radon monitoring systems. Such systems collect air through a small pump and diffuse it into the sensing chamber, where measurements are performed during certain time intervals. Their features change depending on the sensing technique, but all of them usually share a common drawback: they require being calibrated periodically to guarantee accuracy and reliability.
- It updates air samples and readings every hour.
- It provides short-term readings performed on the average of the last seven days.
- It collects long-term readings that are calculated as the average since the last reset of the device.
- It contains a menu button that toggles between short and long term. It also switches off the sound alarm and, when pressed during a certain amount of time, it restarts the sensor memory.
- To verify accuracy and reliability, the sensor auto-checks its internal state every 24 h.
- Guaranteed accuracy: ± 20% or ± 37 Bq/m (the highest of both).
- Typical accuracy: ± 10%.
- Sensor type: diffuse junction photodiode.
- It is actually small in comparison to other radon monitoring tools (its dimensions are 12.0 cm × 7.9 cm × 5.3 cm).
2.2. Academic Monitoring Systems
2.3. Mitigation Systems
- Active soil suction (active sub-slab suction or sub-slab depressurization): This is considered the most reliable and common radon reduction method [8]. It consists of drawing the radon below a building through one or more pipes. Such pipes are inserted through the floor slab into the soil or rock underneath and allow for venting the radon to the air above the home. In homes where the foundations are built with hollow block walls, sub-slab suction can be used in conjunction with block-wall suction to depressurize the block wall. There is also a passive sub-slab suction variety that depends on natural air flows, but it is usually not as effective as active sub-slab suction when there is a high radon gas concentration.
- Perforated pipe, drain tile or sump-hole suction: These systems direct water away from the home foundations by suctioning it through pipes, tiles or by using sump pumps [53].
- Submembrane suction: This is a technique usually applied to crawlspace homes that consists of covering the earth floor with a high-density plastic sheet and then installing a pipe and a fan to draw the radon from under the sheet in order to vent it to the outdoors [54].
- Sealing cracks and openings in the foundations: Theoretically, this method prevents the radon from flowing into the building, but it has to be used in conjunction with another technique, since its use alone has not been shown to lower radon levels significantly.
- Home pressurization or use of air-to-air heat exchangers: These techniques consist of installing devices (a fan or heat exchangers) that blow outdoor air into the house. In the case of home pressurization, the incoming air creates pressure that prevents radon from entering the house, while air exchangers generate a heating or cooling air flow that helps to vent the house.
- Use of natural ventilation: Opening windows, doors and vents creates air flow that mixes outdoor and indoor air, which decreases radon concentration levels. However, note that natural ventilation is only a temporary solution, since it influences air conditioning and home security.
2.4. Analysis of the Related Work
- There are different commercial devices able to detect radon gas concentration, but they are either too expensive for the average householder (accurate readers are available from €1700), slow (e.g., long-term kits) or they do not provide Internet connectivity to access the collected values remotely (e.g., Rstone or Safety Siren Pro Series 3).
- Academic systems are a step ahead of commercial devices in terms of features, but it was found that none were explicitly designed as IoT devices.
- There is a wide range of mitigation systems to reduce radon gas concentration, but such systems are actually either passive approaches (e.g., sealing) or they are not usually connected to radon monitoring devices to act in a smart way.
3. Design of the System
3.1. Architecture
3.2. Sensor Subsystem
- A WeMos Mini D1: This is a ESP8266-based board that provides USB-to-serial connectivity and multiple I/O pins to control other devices.
- A 5-V relay and a transistor: These are able to switch the radon sensor on and off remotely in case any problem arises.
- A voltage regulator and a DC power jack: These enable plugging in the official power adapter of the radon sensor (which works at 18 VDC) and stepping down the voltage to 5 V.
- A 16-to-one mux (CD74HC4067): This is actually inside the radon gas sensor. It is used because the display makes use of twelve parallel signals to communicate through a strobe encoding: seven of them are used for controlling the number shown in seven segments, and five strobe signals select the four digits. Since the number of input pins of the ESP8266 is reduced, the mux needs to be used as shown in Figure 4.
3.3. Service Subsystem
3.4. Visualization Subsystem
3.5. Communication Protocols
4. Implementation
4.1. Implemented Features
- It shows the current short- and long-term radon gas concentration values.
- It plots the historical evolution of the concentration of radon in order to detect trends.
- It is possible to add alerts to the system depending on a threshold that indicates the minimum radon gas concentration. Once the threshold is exceeded, an alert is notified to the user. The configured alerts can be checked with a certain frequency, allowing for sending notifications once an hour, once a day, once a week or once a month.
- Alerts are shown in a specific section of the web dashboards, but they can also be notified to the user through different communication systems (e.g., email, Telegram, SMS).
- The dashboard also shows relevant daily statistics like the mean, minimum and maximum radon gas concentration values.
- It allows for adding multiple radon sensors to the system so that different users can access them in parallel.
- Sensor nodes can be configured remotely, so a technician does not have to go to the place where the sensor is installed to reprogram the firmware.
- Two APIs are provided (Sensor and User API) so that third-parties can interact with the system and develop their own software and add new features to the system.
4.2. Implemented APIs
4.2.1. Sensor API
4.2.2. User API
- GET/history allows obtaining the stored values in a given time range. Three parameters are required: the sensor identifier (SensorID) and the start and end dates.
- GET/threshold allows obtaining the configured alert levels that trigger the different mitigation actions. There are also DELETE and POST methods on this endpoint, which make it possible to eliminate and create new alerts, respectively.
4.3. Visualization and Control Software
4.4. Notification Service
5. Experiments
5.1. Radon Gas Concentration
5.1.1. Urban Home
5.1.2. Galician Rural Home
5.1.3. Research Lab
5.2. Interference Analysis
5.2.1. WiFi Interference under Regular Use
5.2.2. SoC Interference
5.2.3. High-Traffic WiFi
6. Conclusions
Author Contributions
Funding
Conflicts of Interest
Abbreviations
API | Application Programming Interface |
AUV | Autonomous Underwater Vehicle |
COTS | Commercial Off-The-Shelf |
LLD | Lower Limit of Detection |
LRAD | Long-Range Alpha Detector |
NTP | Network Time Protocol |
REST | REpresentational State Transfer |
RTC | Real-Time Clock |
SoC | System-on-Chip |
UHF | Ultra-High Frequency |
WHO | World Health Organization |
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Blanco-Novoa, O.; Fernández-Caramés, T.M.; Fraga-Lamas, P.; Castedo, L. A Cost-Effective IoT System for Monitoring Indoor Radon Gas Concentration. Sensors 2018, 18, 2198. https://doi.org/10.3390/s18072198
Blanco-Novoa O, Fernández-Caramés TM, Fraga-Lamas P, Castedo L. A Cost-Effective IoT System for Monitoring Indoor Radon Gas Concentration. Sensors. 2018; 18(7):2198. https://doi.org/10.3390/s18072198
Chicago/Turabian StyleBlanco-Novoa, Oscar, Tiago M. Fernández-Caramés, Paula Fraga-Lamas, and Luis Castedo. 2018. "A Cost-Effective IoT System for Monitoring Indoor Radon Gas Concentration" Sensors 18, no. 7: 2198. https://doi.org/10.3390/s18072198
APA StyleBlanco-Novoa, O., Fernández-Caramés, T. M., Fraga-Lamas, P., & Castedo, L. (2018). A Cost-Effective IoT System for Monitoring Indoor Radon Gas Concentration. Sensors, 18(7), 2198. https://doi.org/10.3390/s18072198