🔥Use a 4.7mm diameter copper pipe for peak efficiency.
❄️Coil the copper tubing around an aluminum Coca-Cola can for effective cooling.
🔩Employ a 2.5mm diameter stainless steel sleeve as the condenser base.
💡Utilize a slim 1.2mm diameter copper tube as the capillary tube.
🔌Solder a 9-volt battery connector to the pump and fan for flawless operation.
What's the ideal diameter for the copper pipe?
—For optimal performance, use a 4.7mm diameter copper pipe.
What should I coil the copper tubing around?
—For effective cooling, expertly coil the copper tubing around an aluminum Coca-Cola can.
What material should be used for the condenser base?
—Employ a 2.5mm diameter stainless steel sleeve as the condenser base for constructing the condenser.
What diameter should the capillary tube be?
—Utilize a slim 1.2mm diameter copper tube as the capillary tube.
How do I ensure flawless operation?
—Firmly solder a 9-volt battery connector to the pump and fan for flawless operation.
00:00Introduction to the extraordinary effectiveness of a DIY cooling apparatus tailored for beverages.
00:21Insight into using a 4.7mm diameter copper pipe for peak efficiency.
00:47Explanation of expertly coiling the copper tubing around an aluminum Coca-Cola can for effective cooling.
02:03Demonstration of employing a 2.5mm diameter stainless steel sleeve as the condenser base.
04:04Utilizing a slim 1.2mm diameter copper tube as the capillary tube.
05:27Step-by-step guide on soldering a 9-volt battery connector to the pump and fan.
06:32Instruction on skillfully soldering the capillary tube to both the condenser and evaporator using specialized solder and flux.
08:35Commencing the inaugural testing phase to verify the smooth passage of liquefied gas through the intricate network of pipes and capillary system within the conditioner.
