The integration of solar energy into the fire safety system represents a significant step forward in improving the reliability and efficiency of these devices. Traditional security systems generally rely on electricity supplied by the grid, which can be problematic in the event of a power outage during an emergency. Fire has harmful consequences for society, causing human losses and considerable material damage, not to mention the impact on economic activities. To effectively combat this phenomenon, this article proposes the development of an integrated fire protection device, equipped with a solar energy system, guaranteeing energy autonomy and the protection of premises. This device is designed to detect fire outbreaks using sensors. Its design is based on the selection and sizing of various electronic components, including a GSM module, an Arduino Nano, smoke detectors, an alert system, as well as a photovoltaic system for solar energy. For programming and assembly of the electrical circuit, the Qelectrical software is used. In addition, a temperature and humidity sensor is integrated into the alert system, thus forming a control set that ensures the proper operation of the device. Like existing systems, this device helps reduce damage in the event of a fire while operating independently of clean energy sources, respectingthe environment, also meeting the energy needs of the building. It is an ecological, non-polluting solution, suitable even for isolated areas.
Published in | Science Journal of Energy Engineering (Volume 12, Issue 4) |
DOI | 10.11648/j.sjee.20241204.13 |
Page(s) | 91-100 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Fire Protection, Energy Autonomy, Alert System, Solar Energy, Environment, Ecological
Elements | Photos | Roles | Features |
---|---|---|---|
Arduino nano | Main system controller. | 1. Microcontroller: ATmega328 2. Digital Inputs/Outputs: 14 3. Power supply: USB or 5-12V (DC) 4. 6 Analog Inputs 5. Frequency: 16 MHz 6. Memory: 2 KB SRAM, 32 KB Flash | |
Alarm | Alert if an anomaly is detected | 1. Type: sound or visual (LED) 2. Power supply: 5V-12V 3. Response time: < 1 4. Sound: 85 dB | |
Pump | Transfers liquids into the system. | 1. Type: water pump, air pump, or diagram pump 2. Power supply: 5V-12V 3. Pressure: 0.5-2 4. Flow rate: 100-1000 L/h | |
LCD screen | Displays information to the user. | 1. Type: LCD 16x2 or 20x4 2. Interface: 12C or parallel 3. Brightness: backlit or not 4. Power supply: 5V 5. Consumption: < 0.5W | |
Smoke detector | Detects the presence of smoke. | 1. Type: optical or ionic 2. response time: < 30 seconds 3. Power supply: 5V-12V 4. Sensitivity: 0.1 - 1.0% smoke | |
Temperature and humidity detector | Measures the ambient temperature. Relative humidity measurement. | 1. Type: analog (LM35) or digital (DS18B20) 2. Power supply: 3-5V 3. Type: DHT11 4. Power supply: 3-5V 5. Range: 0- 100% RH 6. Range: -55°C to +125°C (DS18B20 |
Names and Type | Photos | Roles | Typical Characteristics and Values |
---|---|---|---|
Solar panels monocrystalline | Converts solar energy into electricity | 1. Nominal power 150 Wc 2. Efficiency 15 – 22% per panel 3. Maximum power current 7.10A 4. Short circuit current 8.1A 5. Dimensions1480 x 680 x 35mm 6. Maximum power voltage 22.6 VDC | |
Battery FREEZE | Stores the energy produced by the panels for later use | 1. Capacity 100Ah 2. Voltage Regulation 12V 3. Cycle use 14.5-14.9V 4. Floating use 13.6-13.8V 5. Intensity 30A | |
SmartSolar MPPT Charge Controllers or Regulators | Manages battery charging and protects it from overcharging and overdischarging | 1. Type Smart Solar MPPT 100/50 2. Voltage 12V/24V 3. Cycle use 14.5-14.9V 4. Floating use 13.6-13.8V 5. Intensity 50 A 6. 95-98% MPPT efficiency | |
Inverter or converter | Converts direct current to alternating current to operate AC loads | 1. Rated power 500W 2 Modified sine type 3. Input voltage 12V DC 4. Output voltage 230V AC 5. Efficiency 85-95% |
Month | Average daily horizontal radiation per month (kWh/m2/) | Average monthly daily irradiance value over the PV field (KWh/m2/d) |
---|---|---|
January | 5.20 | 5.87 |
February | 6.09 | 6.61 |
March | 6.53 | 6.72 |
April | 6.69 | 6.51 |
May | 6.70 | 6.25 |
June | 6.36 | 5.84 |
July | 6.01 | 5.58 |
August | 5.64 | 5.42 |
September | 5.79 | 5.82 |
October | 5.85 | 6.21 |
November | 5.46 | 6.11 |
December | 5.05 | 5.78 |
Receivers | Quantity | Power ratings (W) | Duration of use (H) | Power ratingsTotal (W) | Consumption/day (Wh) |
---|---|---|---|---|---|
Formulas | --- | B | C | D=AxB | E=DxC |
AC receivers | |||||
Television set | 1 | 45 | 10 | 45 | 450 |
Computer | 1 | 60 | 2 | 60 | 120 |
Lamps | 5 | 5 | 6 | 25 | 150 |
Pacpower balance (alternative) | 130 | 750 | |||
Energy Total Eac wh (alternative) | 144.44 | 833.33 | |||
DC receivers | |||||
DC lamps | 3 | 5 | 6 | 15 | 90 |
DC lamps | 2 | 3 | 11 | 6 | 66 |
Brewer | 1 | 26 | 5 | 26 | 130 |
Electronics Component | 1 | 60.67 | 24 | 60.67 | 1456.08 |
Power balance (continuous) | 107.67 | ||||
Energy Total (continuous) | 1742.08 | ||||
Total Energy | 2575.41 | ||||
Maximum power | 252.11 | ||||
Installed peak power | 730.94 |
No. | Designations | Quantity |
---|---|---|
01 | 220 Ohm resistor | 25 |
02 | Capacitor | 06 |
03 | Temperature display | 01 |
04 | Smoke detectors | 01 |
05 | Diode | 13 |
06 | LED | 09 |
07 | Thermistor | 01 |
08 | Transistor | 02 |
09 | LCD temperature display | 01 |
10 | Fan | 01 |
11 | GSM Module | 01 |
12 | 12V pump | 01 |
13 | A SIM card | 01 |
14 | 7812 controller | 01 |
15 | NPN transistor | 01 |
16 | Arduino Nano | 01 |
17 | Programming | 01 |
18 | Solar battery | 02 |
19 | Load controller | 01 |
20 | Converter | 01 |
21 | Installation accessories | 01 |
22 | Solar panel 150Wc | 04 |
A | Ampere |
AC | Alternating Current |
CE | Daily Energy Consumption |
CH4 | Methane, a Hydrocarbon |
CO | Carbon Monoxide |
Cu | Capacity of a Battery |
DC | Direct Current |
D | Degree of Discharge |
DDI | Device Data Interface |
DHT | Humidity and Temperature Sensor |
LED | Light Emitting Diode |
LCD | Liquid Crystal Display |
L/h | Liters Per Hour |
MPPT | Maximum Power Point Tracker |
Nb | Number of Batteries to Use |
Nreg | Number of Regulators |
Iu | Regulator Current |
Smin | Minimum Cable Section |
U | System Voltage |
V | Volt |
W | Watt |
Wc | Peak Watt |
LPG | Liquefied Petroleum Gas |
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APA Style
Ibrahim, M., Gilles, A. R., Madogni, I. V., Macaire, A. (2024). Integration of Solar Energy into Fire Safety System. Science Journal of Energy Engineering, 12(4), 91-100. https://doi.org/10.11648/j.sjee.20241204.13
ACS Style
Ibrahim, M.; Gilles, A. R.; Madogni, I. V.; Macaire, A. Integration of Solar Energy into Fire Safety System. Sci. J. Energy Eng. 2024, 12(4), 91-100. doi: 10.11648/j.sjee.20241204.13
AMA Style
Ibrahim M, Gilles AR, Madogni IV, Macaire A. Integration of Solar Energy into Fire Safety System. Sci J Energy Eng. 2024;12(4):91-100. doi: 10.11648/j.sjee.20241204.13
@article{10.11648/j.sjee.20241204.13, author = {Moussa Ibrahim and Agbokpanzo Richard Gilles and Irénée Vianou Madogni and Agbomahena Macaire}, title = {Integration of Solar Energy into Fire Safety System }, journal = {Science Journal of Energy Engineering}, volume = {12}, number = {4}, pages = {91-100}, doi = {10.11648/j.sjee.20241204.13}, url = {https://doi.org/10.11648/j.sjee.20241204.13}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.sjee.20241204.13}, abstract = {The integration of solar energy into the fire safety system represents a significant step forward in improving the reliability and efficiency of these devices. Traditional security systems generally rely on electricity supplied by the grid, which can be problematic in the event of a power outage during an emergency. Fire has harmful consequences for society, causing human losses and considerable material damage, not to mention the impact on economic activities. To effectively combat this phenomenon, this article proposes the development of an integrated fire protection device, equipped with a solar energy system, guaranteeing energy autonomy and the protection of premises. This device is designed to detect fire outbreaks using sensors. Its design is based on the selection and sizing of various electronic components, including a GSM module, an Arduino Nano, smoke detectors, an alert system, as well as a photovoltaic system for solar energy. For programming and assembly of the electrical circuit, the Qelectrical software is used. In addition, a temperature and humidity sensor is integrated into the alert system, thus forming a control set that ensures the proper operation of the device. Like existing systems, this device helps reduce damage in the event of a fire while operating independently of clean energy sources, respectingthe environment, also meeting the energy needs of the building. It is an ecological, non-polluting solution, suitable even for isolated areas. }, year = {2024} }
TY - JOUR T1 - Integration of Solar Energy into Fire Safety System AU - Moussa Ibrahim AU - Agbokpanzo Richard Gilles AU - Irénée Vianou Madogni AU - Agbomahena Macaire Y1 - 2024/12/16 PY - 2024 N1 - https://doi.org/10.11648/j.sjee.20241204.13 DO - 10.11648/j.sjee.20241204.13 T2 - Science Journal of Energy Engineering JF - Science Journal of Energy Engineering JO - Science Journal of Energy Engineering SP - 91 EP - 100 PB - Science Publishing Group SN - 2376-8126 UR - https://doi.org/10.11648/j.sjee.20241204.13 AB - The integration of solar energy into the fire safety system represents a significant step forward in improving the reliability and efficiency of these devices. Traditional security systems generally rely on electricity supplied by the grid, which can be problematic in the event of a power outage during an emergency. Fire has harmful consequences for society, causing human losses and considerable material damage, not to mention the impact on economic activities. To effectively combat this phenomenon, this article proposes the development of an integrated fire protection device, equipped with a solar energy system, guaranteeing energy autonomy and the protection of premises. This device is designed to detect fire outbreaks using sensors. Its design is based on the selection and sizing of various electronic components, including a GSM module, an Arduino Nano, smoke detectors, an alert system, as well as a photovoltaic system for solar energy. For programming and assembly of the electrical circuit, the Qelectrical software is used. In addition, a temperature and humidity sensor is integrated into the alert system, thus forming a control set that ensures the proper operation of the device. Like existing systems, this device helps reduce damage in the event of a fire while operating independently of clean energy sources, respectingthe environment, also meeting the energy needs of the building. It is an ecological, non-polluting solution, suitable even for isolated areas. VL - 12 IS - 4 ER -