(1) Wet rock compressibility cw = i/kw = (i/v)aav|q=0 (38) where V is wet rock volume and q is the pore fluid flow density (2) Pore volume elasticity ep * 0/♦)»„♦„ (39) where <t> is the porosity and the subscript o references to constant external stress (3) Formation capacitivity s = (cf + epH = 4>Cf+ ap*0 (40) where Cf is the fluid compressibility (4) Pore volume dilaticity dp = n/4.)3a<t>p (41) (5) Pore pressure reactance - -3oPlq=0 (42) Below, we will consider these quan- tities in the case of plausible rock models. One of the main difficulties with regard to the present subject results from the uncertainties as to the pore geometry and connectivity. To obtain a semi-quantitative picture of possible parameter ranges, we will therefore con- sider the two extreme pore models il- lustrated in Figure 2 below. The model shown in Figure 2a in- volves a porosity due to a fluid-filled three-dimensional network of channels of a uniform width h. The number of channels per unit length is n and the porosity is thus <t>=3nh. Let the solid rock compressibility be cr. On the parallel channel model there is an approximately complete rock/fluid pressure contact such that the total compressibility c * (l-4>)cr + <fcf= (l-f)(3/5y) + fcf (43) Obviously, in this particular case the increase in fluid volume/unit volume = d<þ resulting from an increase in pore pressure dp is simply df = c^dp (44) and the formation capacitivity s is thus equal to cw. Moreover, the pore pressure is equal to the negative impos- ed isotropic stress such that the pore pressure reactance y = 1. For later development we use the symbol S0 = (l-*)cr + *cf (45) for the capacitance that applies in the case of the parallel channel model. In general, the expression for the capacitance s will depend on the pore geometry. It is to be noted that because of the completely open matrix, ep and dp cannot be properly defined on this par- ticular model. Turning to the other extreme, the spherical pore model sketched in Figure 2b, we assume that the porosity is quite small, that is, a few % at most. We can then neglect pore-pore interaction. Let the number of pores per unit volume, that is, the pore density be n and the pore radius be R. The porosity is thus <þ = (4tt/3)nR5. Based on the assumptions of small porosity, pore non-interaction and the development in section (12) we find that approximately cw = cr= l/kr where kr is the rock bulk modulus, and using the notation in Table I, the pore volume elasticity ep = nE^ = nnR3/y = 3*/4 (46) and the capacitivity thus s = [ (3/4 y) + cfH (47) For most practical purposes, the first term in the brackets of (47) can be neglected. o ( ) + 2r o - »'■ o O T o Figure 2a. Parallel channel model. Figure 2b. Spherical pore model. To obtain the pore pressure reactance at non-flow conditions, we turn to equations (19) and (20) and find that for spherical pores containing water with Cf=5x 10-10 Pa-1 and p = 2x 1010 Pa Y = (1.35/y)/[(0.75/v) + cfl = 0.125 (48) Turning to general cases, we observe on the basis of (19) and (39) to (42) that Y = *dp/s (49) and using the relation o = kwb where b is the volume strain, equation (42) leads to P = -(♦dpkw/s)b (50) which we abbreviate P = -(«/s)b (51) where s - *dpkw (52) is the dilaticity number. On the parallel channel model cw=l/kw = s and therefore y=l and p = -a. Also, the dilaticity number <5=1. On the other extreme, the spherical pore model with a small porosity and where kr = kw, we obtain from Table I and on the basis of Poisson’s relations that 6 = *dpkw = 1.8nR3/y= 0.72f, (53) In some cases it is convenient to ex- press the pore pressure P ■ -(rs0kw/s0)b (54) where sQ is the formation capacitivity as defined by (45). This can then be ab- breviated p = -(e/sQ)b (55) where c = Ys0kw (56) is the matrix coefficient that is an im- portant dimensionless factor. We observe that in the case of the parallel channel model s = (l/kw), y=l and hence £ =1. But in the case of the spherical pore model we have in the very low porosity limit kw=kr, s = (1 /kr) and y = 0.125. Hence e =0.125 for this limiting case. The relevance of this factor results from the fact that it is at times conve- TÍMARIT VFÍ 1983 — 91

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