DT LAB

HEATING SYSTEM

• The positioning of heating is made on the lower surface and left bottom corner above the heating apparatus this ensured us to use a common battery integration mechanism.
• We used the nichrome wire with a wire sleeve to double layered bottle showed the impact .
• Also, the temperature sensor is in direct contact with the water to measure temperature accurately.
• The present showed the heating of water is done in 20-25min.

Heating System

Components:

• Double layer bottle
• 12v DC connectors
• Nichrome wire
• 12v rechargeable battery
• Wire sleeve
• PVC solvent(glue)
• Temperature display
• Switch button

CHALLENGES FACED WHILE DOING PROJECT

• Shorting problem while heating up the wire .
• Time taking is more for heating water in bottle.
• Accuracy of temperature display.
• various voltage supply.
• Body of bottle was getting hot while heating the water.

Water cooling system

• Connecting the 12v battery to power the DC motor and the thermoelectric Peltier.
• Attaching the heat sink to the thermoelectric Peltier and we ensured proper contact with the water bottle is made and the excess heat can be dispensed through the fan. That’s how compact version cooling system we incorporated.
• Then we verified the functionality of the cooling system by testing its ability to cool the water within the bottle efficiently.
• By attaching the temperature sensor one terminal to the system and the other terminal of the sensor is made to connect with NodeMCU (Threshold cool=6C).
• The present basic model 12V Peltier model cooled water of 300 ml for about 10 – 15 min.

Cooling System

Components used :

• Two 12v batteries
• Heat sink
• DC motor(12v)
• Thermoelectric Peltier(12V)
• Water bottle(stainless steel)

BATTERY MANAGEMENT SYSTEM

• Lithium ion 12v battery are used
• This is secondary (rechargeable) battery
• It can charge through ac supply or external source

Battery Management

SOFTWARE CONNECTIVITY

• We Installed the Arduino IDE software on the computer and

• Connected the NodeMCU board via USB.

• Installed all the necessary board definitions and libraries for the NodeMCU.

• Writing the firmware code for the NodeMCU, which includes WiFi and Bluetooth connectivity, temperature sensing, control logic, and Blynk integration

We connect the temperature sensors to the NodeMCU board using appropriate digital pins. Connect the heating element to a suitable power source and connect it to the NodeMCU. Then connected the cooling element (Peltier module) to a suitable power source and connect it to the NodeMCU. And finally connected the rechargeable battery to the NodeMCU and the charging circuit. Thus everything is made sure to show output in display screen and act manually and also automatically.

A. Display and User Interface:

o Mounted the display module on the front surface of the bottle.

o Connect the display module to the NodeMCU and display relevant information such as temperature, mode (heating/cooling), and battery status.

Fusion and Integrations

• We used BLYNK app platform to monitor regulate accordingly . Then we configured the Blynk app to connect to the Advanced Smart Water Bottle, By modify the NodeMCU firmware code to include Blynk integration, allowed us to control and monitor the water bottle using this app.

• The working is done like configuring the Blynk app interface with buttons, sliders, or other suitable widgets to control the heating/cooling and view temperature readings also we set the threshold values. Then testing the Blynk app connectivity is also done and we ensure seamless communication between the app and the water bottle.

• Every components are placed in compartments and made a good consoled prototype.