PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT
ABSTRACT PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT By RHESA MUHAMMAD RAMADHAN NIM: 13217003 (Bachelor’s Program in Electrical Engineering) At this time, the room disinfection process in hospitals is still done manually by humans. Cleaning staff as manual disinfe...
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Teknik (Rekayasa, enjinering dan kegiatan berkaitan) |
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Teknik (Rekayasa, enjinering dan kegiatan berkaitan) Muhammad Ramadhan, Rhesa PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT |
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ABSTRACT
PROTOTYPE DESIGN AND IMPLEMENTATION OF AN
AUTONOMOUS DISINFECTION ROBOT
By
RHESA MUHAMMAD RAMADHAN
NIM: 13217003
(Bachelor’s Program in Electrical Engineering)
At this time, the room disinfection process in hospitals is still done manually by
humans. Cleaning staff as manual disinfection agents have the potential to be
exposed to hazardous chemicals, Hospital Acquired Infections, and dangerous
pathogens from the doffing process of releasing personal protective equipment after
the disinfection activity. This condition makes the room disinfection process risky
to be done manually. The presence of COVID-19 cases in the world has increased
disinfection intensity in hospitals, especially in doctors' practice rooms. This
increase in disinfection intensity occurs because of the continuous change of room
occupants which could potentially bring the virus into the air column inside the
room. Various kinds of doctor's specialties have made the layout of the doctor’s
office varies. Therefore, in this final project, a robot has been designed with the
ability to disinfect the room air column autonomously, thus helping the cleaning
staffs disinfect the air evenly in various doctor's office rooms. As a limitation, the
robot can only disinfect room air in 4 types of doctor's practice rooms in a closed
condition measuring 4 meters × 4 meters.
The autonomous disinfection robot is designed to have 6 different subsystems,
namely data processing, interface, spray, power supply, drive, and object detection
subsystems. In the data processing subsystem, the distribution of data processing is
made to divide the data processing workload amid limited processing resources.
The interface subsystem is built to connect the user with the robot system. The spray
subsystem is built to disseminate the disinfectant into the air in the form of a mist.
The power supply subsystem is built to provide power to the robot's internal
electronic components. Printed circuit boards are used to integrate electronic
components inside the robot systems. The casing is used as a robot frame, providing
support for the robot's functionality to be able to spray disinfectant, and storing
electronic or non-electronic components that make up the subsystems.
The interface subsystem is implemented using HTML for the front-end and HTTP
protocol for the back-end. Access of the interface subsystem for device control
purposes is done via the web browser on the smartphone. The spray subsystem is
implemented using a TW8001 nozel, a SAKAI MLR PP-25W pump, a switching
component in the form of an IRF520-type MOSFET, and is controlled directly by
the FPGA from the data processing subsystem. The power supply subsystem is
iv
implemented by using 15 pieces of 18650 batteries with a nominal voltage of 3.7 V
which are arranged in a parallel configuration of 5 batteries, then each battery
configured in parallel is arranged in series as many as 3 sets. The power supply
subsystem has a feature to access the remaining percentage of battery charge via
the interface subsystem with 5% resolution. The integration of electronic
components from the entire robotic system is implemented on 4 printed circuit
boards, namely the central board, the movement control board, the data processing
board for the Reinforcement Learning section, and the power supply board. The
casing is implemented in the form of a mixture of acrylic, PETG, and paralon
materials.
The results of usability testing for the interface subsystem reached 87.77%. The
disinfectant mist from the sprayer can reach a height of 54 cm from the base of the
nozzle and an angle of 43.60° and can spray 4.15 mL of disinfectant in 1.92 seconds.
The reservoir in the spray subsystem can accommodate 534 mL of disinfectant
liquid. The power supply subsystem is able to supply power to the robot system up
to 30 minutes 4 seconds. The robot’s casing has a size of 121 cm × 40 cm × 40 cm
with a circular base shape and has the ability to be water resistant up to a discharge
of 109.9 mL/minute.
Keywords: autonomous robot, data processing distribution, indoor air disinfection,
interface, power supply. |
| format |
Final Project |
| author |
Muhammad Ramadhan, Rhesa |
| author_facet |
Muhammad Ramadhan, Rhesa |
| author_sort |
Muhammad Ramadhan, Rhesa |
| title |
PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT |
| title_short |
PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT |
| title_full |
PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT |
| title_fullStr |
PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT |
| title_full_unstemmed |
PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT |
| title_sort |
prototype design and implementation of an autonomous disinfection robot |
| url |
https://digilib.itb.ac.id/gdl/view/66395 |
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1822277612915916800 |
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id-itb.:663952022-06-28T09:25:37ZPROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT Muhammad Ramadhan, Rhesa Teknik (Rekayasa, enjinering dan kegiatan berkaitan) Indonesia Final Project autonomous robot, data processing distribution, indoor air disinfection, interface, power supply. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/66395 ABSTRACT PROTOTYPE DESIGN AND IMPLEMENTATION OF AN AUTONOMOUS DISINFECTION ROBOT By RHESA MUHAMMAD RAMADHAN NIM: 13217003 (Bachelor’s Program in Electrical Engineering) At this time, the room disinfection process in hospitals is still done manually by humans. Cleaning staff as manual disinfection agents have the potential to be exposed to hazardous chemicals, Hospital Acquired Infections, and dangerous pathogens from the doffing process of releasing personal protective equipment after the disinfection activity. This condition makes the room disinfection process risky to be done manually. The presence of COVID-19 cases in the world has increased disinfection intensity in hospitals, especially in doctors' practice rooms. This increase in disinfection intensity occurs because of the continuous change of room occupants which could potentially bring the virus into the air column inside the room. Various kinds of doctor's specialties have made the layout of the doctor’s office varies. Therefore, in this final project, a robot has been designed with the ability to disinfect the room air column autonomously, thus helping the cleaning staffs disinfect the air evenly in various doctor's office rooms. As a limitation, the robot can only disinfect room air in 4 types of doctor's practice rooms in a closed condition measuring 4 meters × 4 meters. The autonomous disinfection robot is designed to have 6 different subsystems, namely data processing, interface, spray, power supply, drive, and object detection subsystems. In the data processing subsystem, the distribution of data processing is made to divide the data processing workload amid limited processing resources. The interface subsystem is built to connect the user with the robot system. The spray subsystem is built to disseminate the disinfectant into the air in the form of a mist. The power supply subsystem is built to provide power to the robot's internal electronic components. Printed circuit boards are used to integrate electronic components inside the robot systems. The casing is used as a robot frame, providing support for the robot's functionality to be able to spray disinfectant, and storing electronic or non-electronic components that make up the subsystems. The interface subsystem is implemented using HTML for the front-end and HTTP protocol for the back-end. Access of the interface subsystem for device control purposes is done via the web browser on the smartphone. The spray subsystem is implemented using a TW8001 nozel, a SAKAI MLR PP-25W pump, a switching component in the form of an IRF520-type MOSFET, and is controlled directly by the FPGA from the data processing subsystem. The power supply subsystem is iv implemented by using 15 pieces of 18650 batteries with a nominal voltage of 3.7 V which are arranged in a parallel configuration of 5 batteries, then each battery configured in parallel is arranged in series as many as 3 sets. The power supply subsystem has a feature to access the remaining percentage of battery charge via the interface subsystem with 5% resolution. The integration of electronic components from the entire robotic system is implemented on 4 printed circuit boards, namely the central board, the movement control board, the data processing board for the Reinforcement Learning section, and the power supply board. The casing is implemented in the form of a mixture of acrylic, PETG, and paralon materials. The results of usability testing for the interface subsystem reached 87.77%. The disinfectant mist from the sprayer can reach a height of 54 cm from the base of the nozzle and an angle of 43.60° and can spray 4.15 mL of disinfectant in 1.92 seconds. The reservoir in the spray subsystem can accommodate 534 mL of disinfectant liquid. The power supply subsystem is able to supply power to the robot system up to 30 minutes 4 seconds. The robot’s casing has a size of 121 cm × 40 cm × 40 cm with a circular base shape and has the ability to be water resistant up to a discharge of 109.9 mL/minute. Keywords: autonomous robot, data processing distribution, indoor air disinfection, interface, power supply. text |