Hydroelastic Cavity Resonators GUNNAR BÖÐVARSSON, SCHOOL OF OCEANOGRAPHY OREGON STATE UNIVERSITY CORVALLIS, OREGON 97331, U.S.A. AXEL BJÖRNSSON, NATIONAL ENERGY AUTHORITY, REYKJAVÍK, ICELAND ABSTRACT Fluids contained in interconnected systems of subsurface cavities are capable of oscillations which we refer to as hydroelastic oscillations. The simplest type of such systems is represented by the borehole-cavity oscillator which is analog to the well known Helmholtz resonator in acoustics. The restoring force is provided by the elasticity of the cavity and the oscillating mass by the fluid column in the borehole. Temperature observations on a flowing thermal borehole in the City of Reykjavik appear to indicate oscillations of this type. A simplified theory of hydroelastic borehole-cavity oscilla- tions is given. INTRODUCTION Ground water bodies embedded in fractured rock consist of a system of interconnected fluid- filled openings with elastic walls. When pro- perly excited, such systems are capable of oscil- lations which we will refer to as hydroelastic oscillations. The fractures act as elastic cavities, which can expand and contract upon changes in the fluid pressure, and the oscillating mass is provided by the fluid. Such systems can be open or closed depending on whether they are connected with a free water surface or not. A particularly simple open system of this type is represented by a fluid filled cavity at depth which is connected with a vertical borehole with a free water level. When the dimensions of the cavity are substantially greater than the diameter of the borehole, this system is ana- 20 JÖKULL 26. ÁR logous to the Helmholtz cavity resonator in acoustics (see Elmore and Heald, 1969). The oscillating mass is provided by the water col- umn in the borehole and the restoring force results from the elasticity of the cavity. Simple estimates indicate that open borehole- cavity oscillators may have resonant frequencies with periods ranging from a few seconds up to a few hours, depending on the dimensions of the elastic cavity and of the water column. These results indicate that oscillations are not likely to be excited in large static systems un- less there is resonance with some component of the earth tides. Resonances in smaller systems with a throughflow of fluid may, on the other hand, be excited by turbulent and other flow induced pressure fluctuations. Since the reson- ant frequencies depend heavily on the dimens- ions of the systems, it may in many cases be of practical interest to monitor hydroelastic oscil- lations. The observed frequencies furnish in- formation on the dimensions of the system under investigation which may not be obtained in other ways. Unfortunately, the observation of oscillations in flowing systems is somewhat more cumbersome than in open static systems where a simple recording of water levels may suffice. There are principally two ways of recording oscillations in flowing systems. First, it is pos- sible to install sensitive pressure transducers in flowing boreholes or other available open- ings. Highly sensitive instruments are now available for this purpose. Second, since pres- sure oscillations generally induce flow oscilla- tions, the monitoring of the flow of boreholes

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