WE SGE TesDison Test Results

SUMMARY OF THE TESTED RESULTS OF THE TESDISON UNIT FOR ENGINEERING PURPOSE ONLY

Testing Dates: From September 17, 2019 to September 18, 2019

Reporting Date: October 3rd, 2019

The TesDison Unit was developed to maximize electric output; providing continuous renewable energy from electricity that has been stored in batteries.

Components of the TesDison Unit

The major components of the prototype unit are;

• Two 12-volt batteries
• A DC Electric Motor
• A Generator
• An Inverter
• An AI Smart Chipset Charger

Functionality
The two 12-volt batteries deliver the initial power to get the system cycling. Energy flows from the two batteries to a DC Electric Motor which powers the Generator. The Generator puts out a steady power supply of 110VAC. This power is directed by the AI Chipset Charger to charge both batteries though an internal Inverter.

Finally, the Inverter converts the 12-volt power from the 2 batteries to 110 VAC of clean power supply. In this test, we used two simple household appliances to consume the capacity; an Iron and an A/C unit.

This technology has proven to increase the output of the initial stored voltage and amps exponentially, effectively creating additional energy capacity.

Objective-Engineering Test
SGE contracted National Technical Systems (NTS) to test the SGE TesDison equipment and verify the stated performance. NTS independently ran the TesDison Unit and monitored, measured and documented the entire process described above; measuring the flow of electricity at specific points in the TesDison system verifying that the unit operates without any outside power source and functions as a stand-alone energy supply increasing energy capacity beyond the mechanical limits.

The Test

On September 17, 2019 NTS performed the test and provided the results in the attached report.

The test was run over a two-day period.

Day One Test

Run the test with the TesDison Unit Off
The appliances (iron and A/C unit) were powered using only the two 12-volt batteries hooked up to the inverter. The appliances were set to the same pre-established level each day;

• Iron on maximum setting on the dial
• A/C unit set to cool, 66-degree setpoint.

This test was to ascertain a baseline of EXACTLY how long it takes to completely drain the batteries using the two appliances. The TesDison System was bypassed and was not used. The time was monitored with multiple stopwatches for validation. Periodic measurements were taken during the test, checking;

• Both Batteries with load
  • Measuring volts and amps and noting the time of measurement
• The Inverter with load
  • Measuring volts and amps and noting the time of measurement
• Continue to measure the load from each appliance for the entire test
  period each second
  • Measuring volts and amps and time

The test concluded when the inverter shut off due to the batteries running out of
power/capacity. Noting exact time at shut off.

• The baseline time to drain the batteries was established at 31 minutes.

Day Two Test

Run test with the TesDison System On.

Again, the appliances (iron and A/C unit) were run using the two 12-volt batteries, this time hooked up to the TesDison Unit then to the inverter to power the appliances. The appliances were set to the pre-established levels of the previous day; The Day Two Test was run to measure the exact time it would take for the appliances to completely drain the batteries when assisted by the TesDison Unit. The time was monitored with multiple stopwatches for validation. The same exact periodic measurements were taken during the test; The test concluded when the inverter shut off due to the batteries running out of power/capacity. Noting exact time at shut off.

• The time to drain the batteries Using the TesDison Unit was measured at 98 minutes.

Conclusion

In this test, with the SGE TesDison Unit turn on was able to deliver a constant flow of 110 VAC for more than 3 times the duration of the batteries alone.