Wearables for Industrial Work Safety: A Survey
Abstract
:1. Introduction
2. Industrial Wearable Devices
3. State-of-the-Art Techniques in the Field of Industrial Wearables
3.1. Data Collection and Wearable Metrics
3.2. Data Transmission
Category | Technology | Frequency | Max. Data Rate | Refs. |
---|---|---|---|---|
Short-range (<100 m) | RFID | 0.86 GHz | 40 kbps | [132] |
Zigbee | 868 MHz, 915 MHz, 2.4 GHz | 20 kbps, 40 kbps, 250 kbps | [125] | |
Bluetooth | 2.4 GHz | 1–3 Mbps | [123,133] | |
BLE | 2.4 GHz | 125 kbps–2 Mbps | [123,133] | |
Mid-range (100 m–5 km) | IEEE 802.11b | 2.4 GHz | 1–11 Mbps | [123,134] |
IEEE 802.11g | 2.4 GHz | 6–54 Mbps | [123,135] | |
IEEE 802.11n | 2.4/5 GHz | Up to 600 Mbps | [123,135] | |
IEEE 802.11ac | 5 GHz | Up to 1 Gbps | [123,135] | |
Long-range (>5 km) | LoRa | 915–928/863–870/433 MHz | 50 kpbs | [136,137] |
Sigfox | 868/902 MHz | 100 bps | [129] | |
LTE | 3GPP frequency bands | 100 Mbps | [130] | |
LTE-M | 3GPP frequency bands | 1 Mbps | [138] | |
NB-IoT | 3GPP frequency bands | 250 kbps | [139,140] |
3.3. Localization Techniques
4. Challenges and Future Perspective
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Conflicts of Interest
Abbreviations
AoA | Angle of Arrival |
AoD | Angle of Departure |
AQI | Air Quality Index |
BLE | Bluetooth Low Energy |
DV-HOP | Distance Vector-Hop |
ECG | Electrocardiogram |
EEG | Electroencephalogram |
eMBB | Enhanced Mobile Broadband |
EMG | Electromyography |
GNSS | Global Navigation Satellite System |
GPS | Global Positioning System |
HAV | Hand-arm Vibration |
IEEE | Institute of Electrical and Electronics Engineers |
IIoT | Industrial Internet of Things |
ILO | International Labor Organization |
IoT | Internet of Things |
IWSN | Industrial Wireless Sensor Networks |
LoRaWAN | Long-Range Wide-area Network |
LPWAN | Low-power Wide-area Network |
MDPI | Multidisciplinary Digital Publishing Institute |
mMTC | Massive Machine-type Communications |
NB-IoT | Narrowband IoT |
RFID | Radio Frequency Identification |
RSSI | Received Signal Strength Indicator |
TDoA | Time Difference of Arrival |
ToA | Time of Arrival |
UE | User Equipment |
URLLC | Ultra-Reliable and Low Latency Communications |
UVI | Ultraviolet Index |
VLC | Visible Light Communications |
WHO | World Health Organization |
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Function | Sub-Functions & Description |
---|---|
Monitoring (M) Fitness trackers, smart rings, smart glasses, patches/ sensors attached to the body, smart clothing, implantable wearables, etc. | Monitoring and control of vital parameters of workers. Information about vital parameters (heart rate, blood pressure, body temperature, brain activity, etc.) gives the employer (organization, safety manager, administration) and the worker himself an idea on the readiness of the latter for the work process from a physical, less often psychological, point of view [31,32]. Monitoring of environmental parameters at workplaces. Knowing such parameters as the temperature at the worksite, atmospheric pressure, level of radiation, and so on allows an organization to control the overall environmental situation at the factory, prevent emergencies, timely organize the evacuation of people, provide a worker with proper Personal Protective Equipment (PPE). Moreover, by combining environmental and vital parameters, it is possible to track environmental impacts on human health in hazardous industries such as the chemical industry [33,34]. |
Supporting (S) Exoskeletons, patches (to control the position of the body when lifting heavy objects), wearable robots | Increasing the physical capabilities of the workers. Some industries envisage lifting and transferring heavy objects, which is often associated with musculoskeletal injuries. Wearable items such as exoskeletons support the musculoskeletal system to prevent damage [35,36,37]. Facilitating communication between workers. Due to their small size, weight, and comfortable attachment to the wearer’s body, wearables such as headsets with embedded hand-free microphones, for example, are much more convenient than phones and able to provide communication between workers without distracting them from the work process. (hand-free microphones embedded in headsets/helmets) [38]. Simplification of information management. Wearable devices provide secure transmitting, storage, displaying information, and fast access to documents and notifications [39]. Performing industrial design. The use of AR enables creating virtual diagrams and graphs that facilitate better understanding by workers [40]. |
Training (Tn) Smart glasses, helmets, heads-up display | Training of the workers. Some wearable devices can track the correctness of the actions performed by the worker, providing him with a detailed report (for example, determining the correct posture using biomechanical analysis). The worker can analyze his mistakes to prevent them in the future. Moreover, using Virtual Reality (VR) and Augmented Reality (AR) helmets, it is possible to train workers on complicated operations before performing them in reality, thereby reducing the likelihood of injury [36,40]. |
Tracking (Tc) Smart bracelets, smart clothes, smart boots, digital pedometer, etc. | Monitoring of location parameters of workers. The worker’s location is one of the most important parameters when we are talking about ensuring work safety in the industry. By knowing each employee’s location, the safety manager can efficiently organize evacuations, distribute help and workforce, prevent unauthorized access to the worksite or equipment, and so on [41]. Preventing struck by moving machinery. Tracking of object locations and proximity detection sensors allow avoiding a collision that is one of the most spread accidents in industries [33,41]. Creating a comprehensive picture of the whole production process. Thanks to wearables, managers can see the real-time location of workers and equipment, which allows them easily redistribute labor between operating sites and more effectively allocate resources [41]. |
Industry Branch | Functions (See Table 1) | Examples of Applications |
---|---|---|
Mining | M, Tc | US-based Guardhat to prevent injuries combining rugged helmets with microphones, cameras, and track sensors [42]. Guardhat is currently integrated into a lot of mining operations. |
Chemical | M, Tc | MyExposome developed wristbands that can detect chemical exposures during the day [34]. |
Forest products, construction | M, Tc, S | SolePower company released smart boots [41]. It is equipped with many various modules, particularly GPS and RFID, to determine the wearer’s location. Besides, they are very durable, so they can easily withstand many ordinary adverse external influences. |
Crude oil production | M | Smart Helmet by VRMedia Srl. was applied by the third-largest oil and gas service company in the world Baker Hughes to reduce downtime and increase safety at the workplace [43]. |
Transportation, Shipping | M, Tc, S | Kinetic presents a wearable device called REFLEX that is equipped with sensors and modules performing biomechanical analysis [36]. It is worn on the belt or waistband and can determine whether the posture is correct or not and notify the user by vibration when risky movements arise. |
Metric | Description | Example Accuracy | Examples |
---|---|---|---|
Blood pressure | The pressure that blood puts on the walls of blood vessels. There are systolic or upper (normal value: less than 120 mmHg) and diastolic or lower (normal value: less than 80 mmHg) blood pressure [45]. The average working range of blood pressure sensors is 0–320 mmHg [46,47]. | 86% [48] | Arm cuffs with attached sensors [49], cuff-less blood pressure sensors [50] |
Calorie | A unit equal to the amount of heat needed to increase one gram of water temperature by one degree Celsius. There are several ways how to calculate the number of calories (e.g., based on the number of steps or heart rate [51]), resulting in a wide range of wearables providing this function. | >91% (walking); >90% (running) [52] | Accelerometers, pressure sensors in fitness bracelets, smart shoes [51], etc. |
Electro- cardiogram (ECG) | The electrical activity of the heart [49]. The unit of measurement is Volts. ECG is the main diagnostic method for detecting cardiovascular diseases such as hypertrophy, heart attack, arrhythmia [53]. | >90% [54] | Skin electrodes [49] in clothes [55], chest straps [56], etc. |
Electro- encephalo- gram (EEG) | The electrical activity of the brain [57]. The unit of measurement is Volts. EEG is used to identify and predict brain-related diseases (e.g., Alzheimer’s disease, epilepsy, dementia) [58]. In addition, it also used for the emotion detection [59,60]. Until now, ECG, EEG, and EMG are performed mainly in medical institutions. However, there are already some wearable devices on the market for such measurements. | >86% [59,60] | Headset [57,61] |
Electro- myography (EMG) | The electrical activity of the muscles [49]. The unit of measurement is Volts. When measuring EMG, the critical point is the exact position of the electrodes on the muscles. EMG is used to identify the muscle traumas and monitor the recovery tendency after such traumas [62]. | >90% [63] | Skin electrodes [49] embedded in bracelets, waist straps [64], clothes [65]. |
Glucose | The level of sugar in the blood. It is measured in grams per liter or moles per liter. High glucose level identifies diabetes, the symptoms of which are quite wide, ranging from visual impairment to increased fatigue and depressive episodes [66,67] | >95% [68] | Strip-base [69], implantable [70] glucose sensors, smart tattoos [71] |
Heart rate and pulse | Heart rate is the number of heartbeats per minute. Pulse is the number of vibrations of the aortic walls. Pulse may be a less accurate characteristic in pathologies (for example, extrasystole) since not all heartbeats lead to the formation of a pulse wave [72]. Critical boundaries usually range between 40-200 beats per minute and depend on current activity, gender, age, health, type of activity, etc. | >76% [73] | Pulse oximeter [74], chest [75] and wrist straps [69], fitness bracelets |
Heart sounds | Sounds that appear due to a change in blood flow, vibration of the surrounding tissues of the heart, and large vessels. The conventional way to measure heart sounds is phonocardiograph [76]. However, there are already some wearable solution [77]. | >80% [77] | Wrist band [77] |
Location- related metrics | Metrics related to identifying the object’s position: coverage, accuracy, power consumption, price of the wireless technology, etc. Localization technologies are considered in more detail in Section 3.3. | NA | Wide range of wearables |
Motion- related metrics | This metric refers to identifying the parameters of the human movements that are also called biomechanical analysis [78,79]. The range of the wearables for which this metric is used is very wide since the measured parameters could be very different: from detection of the velocity and speed to determining if the posture correct or not. | NA | Accelerometer, gyroscope [80], exoskeletons, pressure insoles, e-textile [78] |
Perspiration or sweat | A liquid excreted from the skin’s sweat glands [81]. Sweat is the second body fluid after the blood that contains the richest range of biomarkers like glucose, pH, cortisol, etc. [82]. Usually, this metric is used in sport or healthcare areas. | >99% [83] | Sweat collectors, skin patches [82], smart watches [84] |
Temperature | A measure of the ability of the body to generate heat [49]. However, the normal temperature range for a healthy human is 36.16–37.02 °C [85], and the widest recorded range is 24–44 °C [86], usually the range of the wearables measuring temperature is wider. | >99% [87] | Temperature sensors [88,89] and skin patches [90] |
Metric | Description | Examples |
---|---|---|
Air Quality Index (AQI) | An index shows the degree of air pollution in a certain area [91]. It is calculated based on measured concentrations of pollutants and government-set limits for those concentrations. The list of measured pollutants can include ozone, carbon monoxide, sulfur dioxide, nitrogen dioxide, dust, etc. The possible values of the index are between 0 to 500. The scale is divided into ranges, usually 5 or 6, each corresponding to a specific air quality rating, from good to hazardous. The influence of high AQI levels (101 and above) on the human body varies depending on the predisposition (great age, heart/lung diseases), and could lead to such diseases as lung cancer, stroke, pneumonia, etc. [91] | Gas sensors (e.g. CO2 sensor [92]) |
Atmospheric pressure | The pressure exerted by the weight of the atmosphere on the surface (of the Earth or another planet) below it [93]. This metric is necessary for jobs in low (pilots) or high (divers) barometric pressure conditions. On average, the measurement range of pressure sensors is from 300 to 1100 hPa with an error of 0.5 hPa. Extra low or extra high atmospheric pressure cause respiratory, heart, neurological changes, barotraumas, decompression illness, etc. [94,95] | BMPxxx sensor group [92], barometers embedded in bands, smartwatches, glasses [96], etc. |
Light intensity | The strength of light produced by a specific lamp source measured in lux [97]. The light intensity’s recommended levels in different cases can be found in the document issued by the National Optical Astronomic Observatory [98]. Both excessive and insufficient lighting in the workplace can lead to visual impairment. A wide range of health effects of lighting is observed in working conditions at night or in underground sites, including various types of cancer, irregular sleeping habits, and cardiovascular disorders [99,100]. Significantly, an insufficient illumination intensity is considered as causing an additional increase in the rate of accidents in low-light environments, such as construction areas, warehouses, and tunnels [101]. | Motion, traffic, ambient light sensors [20], e.g. [102] |
Noise level | The amplitude level of the undesired background sound [103] is measured in dBA. Constant sound above 80 dBA leads to the physiological effects and above 100 dbA—to the hearing damage, [104]. | Sound sensors, dynamic microphones [20] |
Radiation | An energy from a nuclear reaction [105]. Nowadays, it is measured in Sv (Sievert). However, rem (roentgen equivalent man) units also could be found in the literature. US Nuclear Regulatory Commission has set a radiation limit of 5 rem or 0.05 Sv [106]. Even an acceptable level of radiation during a long period of time (what is typical for radiation industry employees) can be a reason for irreversible changes in the body, in particular, the risk of cancer increases. High doses lead to the vomit, skin burns, can cause death [107] | Radiation detectors [108] |
Relative Humidity | The amount of water that is present in the air compared to the greatest amount it would be possible for the air to hold at that temperature [109]. The hygienic norm of relative humidity for humans is 30–60%. With low humidity, the body becomes dehydrated, and the risk of bacteria entering the human organism increases. High humidity can cause overheating, increased perspiration rate, and promotes the appearance of allergens (mold, fungi, dust mites) [110,111]. | Temperature/humidity sensors [112] |
Temperature | Ambient temperature, which is most often expressed in degrees Celsius. The the typical range of temperature sensors is −40 to 125 degrees Celsius °C [82]. The survival limit for the person is between −40 °C [113] and 48 °C. For the best performance the optimal ambient temperature is 22–26 °C [114]., | Temperature/humidity sensors [82,112] |
Ultraviolet index (UVI) | An index shows the degree of ultraviolet radiation from the sun at a particular time and place. For measuring UVI World Health Organisation (WHO) proposed a linear scale beginning from 0 and without an upper border. There are 5 ranges: low (UV: 1–2), moderate (3–5), high (6–7), very high (8–10), extreme (11+) [115]. The sun exposure with UV higher than 7 can lead to serious damage of eyes (e.g., snowblindness), skin (burns, skin cancer, skin aging), and overall immune system [116]. | UV radiometers and dosimeters embedded in wrist bands, smartwatches, clips, etc. [117] |
Technology References | Localization Techniques | Typical env-t. | Accuracy | Additional Details |
---|---|---|---|---|
GNSS [147] | Time-based | Outdoor | cm-level | Global, not applicable indoors, still considered as high consuming for industrial wearabes, however, some companies already started to present ultra-low power GNSS [148] |
Wi-Fi [149,150] | Time-based, Angle-based, Power-based | Indoor | m-level | Nowadays, Wi-Fi fingerprinting (FP) is one of the most promising localization approaches for industrial wearables due to good accuracy and relatively low cost. The disadvantage of this approach is high consumption in terms of power and efforts spending on the training step |
BLE [151] | Time-based, Power-based | Indoor | m-level | Another perspective technology for indoor localization in IIoT [152] with such advantages as easy deployment, low cost, and low power consumption. However, the accuracy of the method is not very high, and supplementary algorithms are required to improve it [153]. |
UWB [150,154] | Time-based, Angle-based | Indoor | cm-level | This method provides the highest accuracy of the localization, requires not much power, has immunity to fading, applicable even in the case of underground worksites. However, it is hard to deploy [155,156]. |
LoRa [157,158] | Time-based, Power-based | Outdoor | 100 m-level | The key advantages of this technology are coverage range (up to 20 km), low consumption, bigger stability than in case of WiFi and BLE [159]. However, low accuracy prevents the spread of the technology as a localization solution. |
Sigfox [160,161] | Power-based | Outdoor | 100 m-level | Advantages and disadvantages are similar to LoRaWAN technology. |
RFID [132,162,163] | Power-based | Indoor | cm-level | This technology ensures high precision but in a low range (approx. 15 m). |
Angle-based | Indoor | m-level | Less accurate than passive RFID but has bigger range (approx. 150 m). |
Challenge | Groups | Refs. | Possible solutions |
---|---|---|---|
Localization accuracy indoors/outdoors | T | [173,174] | Applying of ML algorithms to identify missing values, predict the number of obstacles and distance between RX and TX |
[175,176] | Seamless localization to provide smooth tracking both indoor and outdoor | ||
Connectivity solutions and propagation models for underground work sites | T | [177,178] | Application requirement-based selection of connectivity solutions, developing of empirical and industrial environment-specific propagation models with on-body/off-body/body-to-body communications |
Power consumption and supply of a big amount of devices | T | [136,179] | Energy harvesting approaches: harvesting from the sunlight, motions, temperature gradients, etc. |
Privacy and security | T, S, D | [180,181] | Elliptic Curve Cryptography (ECC) and other lightweight cryptography |
[182] | Development of strong authentication schemes | ||
Location data privacy | S, D | [183,184] | Adding noise to the exact coordinates on the device side before transmitting it to the cloud |
[185,186] | Transmission of the location-related function instead of the coordinates | ||
Social resistance | S | [18,92] | Development of the simple and detailed manual, video guidance and provision of the constant support to eliminate the problem of low technical skills of users; |
[187,188] | Usage of Technology Acceptance Models (TAM) to estimate key factors affecting the level of social resistance and rearrange the process implementation of the technology accordingly | ||
[189] | Involving of the employees in the process of the choice of wearables | ||
[190] | Data flows transparency | ||
Heterogeneity of the IIoT devices | D, SD | [191] | Application of the data fusion approaches on the hardware level, seamless integration on the protocol level |
Placement of preprocessing and processing entities | D | [192,193] | Optimization of data placement, dynamic computation resource allocation, computation offloading techniques. |
High cost of wearables and its coupling with other technology in big industries | E | [18] | Development of one-size wearable to be used for data acquisition by different workers during different shifts |
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Svertoka, E.; Saafi, S.; Rusu-Casandra, A.; Burget, R.; Marghescu, I.; Hosek, J.; Ometov, A. Wearables for Industrial Work Safety: A Survey. Sensors 2021, 21, 3844. https://doi.org/10.3390/s21113844
Svertoka E, Saafi S, Rusu-Casandra A, Burget R, Marghescu I, Hosek J, Ometov A. Wearables for Industrial Work Safety: A Survey. Sensors. 2021; 21(11):3844. https://doi.org/10.3390/s21113844
Chicago/Turabian StyleSvertoka, Ekaterina, Salwa Saafi, Alexandru Rusu-Casandra, Radim Burget, Ion Marghescu, Jiri Hosek, and Aleksandr Ometov. 2021. "Wearables for Industrial Work Safety: A Survey" Sensors 21, no. 11: 3844. https://doi.org/10.3390/s21113844
APA StyleSvertoka, E., Saafi, S., Rusu-Casandra, A., Burget, R., Marghescu, I., Hosek, J., & Ometov, A. (2021). Wearables for Industrial Work Safety: A Survey. Sensors, 21(11), 3844. https://doi.org/10.3390/s21113844