Today, usage and storage of electricity are crucially important. A thorough and accurate knowledge of how electricity behaves is necessary to continue improving technology, In order to confirm and expand our current knowledge of electronics and methods of energy storage, I have chosen to design an electrical capacitor to test the effect of physical flowing of a liquid on its ability to keep a capacitor changed. If successful, the results of this project may lead to new insights on energy storage and design of electrical equipment. Methods/Materials: I built a capacitor within a liquid circulation system so as to allow measurement of the electrical properties of the plates. The plates, made out of aluminum, are fixed inside an acrylic plastic box with a loose top. The box has an aquatics pump attached that pumps liquid through at a relatively high speed of [insert actual estimation here). The system can be filled or emptied through the removable top of the acrylic box, and the flow rate can be impeded to desired levels with a ball valve flow regulator. Capacitance is measured with a capacitance meter that has two leads, each attaching to different plates within the apparatus. To measure the capacitance with flow, the pump is stoned until the fluid appears to be moving consistently throughout the system. The capacitance meter is then turned on and read. I tested this capacitor with distilled water and an oleic acid solution in ethanol. Results: The design is capable of observing electrical effects of flow of a fluid. The distilled water showed not only change in capacitance due to flow, but also a gradual drift in the data over time that may possibly be memory based, or affected by past electrical environments of the water. This drift was unseen in the oleic acid solution, which did not show much change in capacitance due to flow or over time. Conclusions/Discussion: The results showed that with a liquid such as water with a much higher polarity and dielectric constant may be affected in significant ways by the change in the flow rate, The design has not shown any apparent flaws and has succeeded in observing flow-dependent capacitance. The nature of the effects of flow on capacitance may be more thoroughly examined in future studies. Summary: The purpose of this project was to look at one way to investigate the effect of volumetric flow of a liquid on its ability to keep a capacitor charged. The results could be further investigated with future studies on the effect of applied electrical fields on water and other polar fluids.