So the actual testing time came, I connected the cold circuit with two water pumps and a couple of full bore flexible connection hoses and gate valves to the pumps for easy replacement. I filled the cold circuit with a 20% mixture of food grade glycol and pressurised it to around 1 bar. The glycol is required to lower the freezing temp of the liquid but it comes with an operational cost. The specific heat capacity of glycol is less than water and it makes the liquid more viscous, especially at low temperatures, so makes the flow rate drop and the pump work harder.
For experimental purposes, I simply connected the hot circuit with a single water pump running into a 35 litre builders bucket filled with water. I placed a thermometer in the bucket so I could measure the temperature over time and I also measured the power input to the heatpump.
I switched on the unit, first it did a system check, then the cold circuit pumps started up, followed a minute later by the hot circuit pumps. Soon after the compressor started up. Almost instantly the gauges on the exterior of the unit move in opposite directions, the evaporator is getting colder under the partial vacuum as the refrigerant gas boils as it turns from a liquid into a gas and the condenser is getting hotter under higher pressure as the refrigerant gas is compressed and turns from a gas back into a liquid thus giving up its latent heat. The hot water output feels slightly warm, with the cold circuit gets colder with condensation forming on the ground loop pipes.
Test setup
Water temperature is rising
Pressure gauges showing the high pressure condenser (hot) and the low pressure evaporator (cold) temperatures
A constant increase of 2 degrees per minute in the 35 litre builders bucket, from 18 degrees all the way up to 58 degrees in 17 mins when the high temperature tripped out the compressor. I have calculated that equates to a constant 5.7kW of heat output. The electricity consumption gradually increases in line with the compressor pressure, thus reducing the COP value. The ground loop rapidly drops in temperature for the first 5 minutes, then becomes constant.
