Viscosity Models and Effects of Dissolved CO2 - Energy & Fuels (ACS

Jul 12, 2012 - Enhanced safety of geologic CO 2 storage with nanoparticles. Harpreet Singh , Akand Islam. International Journal of Heat and Mass Trans...
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Viscosity Models and Effects of Dissolved CO2 Akand W. Islam* and Eric S. Carlson Department of Chemical and Biological Engineering, The University of Alabama, Tuscaloosa, Alabama 35487, United States ABSTRACT: A comprehensive study is carried out on viscosity modeling for the geologic sequestration of CO2 in the pressure and temperature range of 1−600 bar and 20−105 °C, respectively. For the liquid phase, we present viscosity models for pure water (H2O), brine (H2O + NaCl), H2O + CO2, H2O + NaCl + CO2, and typical seawater compositions. In each case, we attempted to develop very accurate formulations having fewer parameters than existing models. Because of their simpler forms these also help obtain some computational speedup. The effects of dissolved CO2 are studied extensively. For liquid phase viscosity calculations we have found that, if the presence of CO2 is neglected, deviations can be even 38% when the solution is CO2 saturated and, with 2% (by weight) CO2 dissolution, the difference is 0.6−8%. the lower is its resistance to flow and the displacement by another fluid. Therefore, accurate prediction of viscosity is extremely important. Though not addressing simulation of CO2 sequestration, the authors8,9 have comprehensively investigated the sensitivity of reservoir simulations to uncertainties in viscosity for both liquid and vapor phases. In general, the viscosity change of brine with CO2 saturation is neglected in the developed simulators.10−14 This is because there is no model available in the literature for the effect of dissolved CO2 on water/brine viscosity. However, viscosity is directly related to density, and dissolution of CO2 may cause density variations of 2−3%.4,15 When injecting CO2, the plume has a tendency to flow upward. However, a small amount of CO2 will dissolve into the water; under the influence of the small density difference, that water has the tendency to flow downward.16,17 Tumasjan et al.18 showed that the viscosity of water varies from 1.0 to 1.3 cP for 4% (by weight) dissolved CO2. Thus it is important that CO2 dissolution be considered while modeling viscosity. In this paper, we will present some simple empirical formulations for computing the viscosity of pure water, brine (H2O + NaCl and H2O + NaCl + CO2), and typical seawater (having 3.5% salinity) for the pressure and temperature range of a saline aquifer at 1−600 bar and 20−105 °C, respectively.19 We will also analyze how viscosity varies quantitatively for CO2 dissolution in the aqueous phase.

1. INTRODUCTION Increasing atmospheric concentrations of greenhouse gases are suspected of causing a gradual warming of the Earth’s surface and potentially disastrous changes to global climate. Because CO2 is one of the major greenhouse gases, storage in subsurface formations is being explored as a viable option to limit the accumulation of greenhouse gases in the atmosphere. Carbon sequestration, sometimes broadly referred to as carbon management, is a way to reduce greenhouse gas emissions while still enjoying the benefits of fossil fuel use. This is a complementary approach to the current CO2 mitigation efforts of improved energy efficiency and increased use of noncarbon energy sources. These days, much attention is given to the carbon management option because it is very compatible with the large energy production and delivery infrastructure now in place, nonfossil energy sources face large barriers, renewables are very expensive, and nuclear energy has safety concerns. Sequestration covers technologies that capture carbon at its source (e.g., power plants, industrial processes) and direct it to nonatmospheric sinks (e.g., depleted oil and gas reservoirs, deep saline formations, coal seams, hard rock caverns, deep ocean) as well as processes that increase the removal of carbon from the atmosphere by natural processes (e.g., forestation1), which are widely available but currently have a lack of effective uses due to the great potential of storage. The most promising places for sequestration are aquifers.2,3 Accurate evaluation of the capacity of a saline aquifer for CO2 sequestration and of the fate of the injected fluids in sedimentary basins requires analysis of the thermophysical properties of CO2 and brine. The thermophysical properties include thermodynamic properties, e.g., PVT (pressure−volume−temperature) behaviors and transport properties, e.g., viscosities, thermal conductivities, and diffusion coefficients. Our previous studies4−6 contain comprehensive investigations on PVT behaviors. This study focuses on one of the primary transport properties, viscosity, and presents some simpler and more efficient tools to compute the viscosity of aqueous and gaseous phases in CO2 sequestration. For any multiphase flow system, viscosity plays an important role. Viscosity characterizes the fluids’ resistance with respect to deformation under shear stress.7 The lower a fluid’s viscosity, © 2012 American Chemical Society

2. VISCOSITY OF PURE WATER Very well established formulations for the viscosity of H2O are available for a wide pressure and temperature range.20−26 The most recent IAPWS Formulation27 2009 has more than 63 parameters based on P−T of water (subcritical, supercritical, etc.), covers up to 10 000 bar, and 900 °C, respectively. Here, simpler correlation with fewer parameters for the viscosity calculation applicable in our interested P−T range is proposed. The correlation is given as a function of P Received: April 12, 2012 Revised: July 12, 2012 Published: July 12, 2012 5330

dx.doi.org/10.1021/ef3006228 | Energy Fuels 2012, 26, 5330−5336

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Table 1. Coefficients of Eq 1 i

a

0 1 2 3

9.03591045 × 1001

b

c

3.40285740 × 10 8.23556123 × 1008 −9.28022905 × 1008 04

d −02

1.40090092 × 10 4.86126399 × 10−02 5.26696663 × 10−02

−1.22757462 2.15995021 −3.65253919 1.97270835

× × × ×

10−01 10−02 10−04 10−06

Figure 1. Deviation between calculated viscosity from IAPWS09 and eq 1.

Table 2. Coefficients of Eq 2 i

a

0 1 2 3

1.34136579 × 1002

b

c

d

−4.07743800 × 1003 1.63192756 × 1004 1.37091355 × 1003

−5.56126409 × 10−03 −1.07149234 × 10−02 −5.46294495 × 10−04

4.45861703 × 10−01 −4.51029739 × 10−04

isotherms (30, 50, 80, and 100 °C). From this figure it is clear that maximum divergence (∼0.08%) occurs at 30 °C when pressure is low. Otherwise divergences lie within 0.05%. Because our formulation is simpler than that of IAPWS09, it can help to obtain some computational speedup. For instance, IAPWS09 takes 9.0 ms to compute the viscosity of pure water where our model spends 2.0 ms, meaning it is around 5 times faster. These computational times are produced in a notebook of average configuration (3 GB RAM, Dual-core CPU T4500 @ 2.3 GHz), programmed in Python 2.6 (www.python.org). The timing variation here is in milliseconds for the viscosity calculation itself; however, it can contribute to noticeable computational efficiency after integrating with a large simulator (i.e., numerical

and T, where 3

μH O = a0 + 2

3

∑ bi exp(−ciT ) + P ∑ di(T − 293.15)i i=1

i=0

(1)

Parameters of eq 1 are estimated by regressing the values from calculations of the IAPWS Formulation 2009 (IAPWS09). The coefficients a, b, c, and d are reported in Table 1. P is in MPa. Viscosity values of pure water can be regenerated by eq 1 with a maximum 0.05% deviation as compared to IAPWS09, where deviation = ((lit. − cal)/(lit.)) × 100. Parts a−d of Figure 1 show comparisons of calculations at different 5331

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Figure 2. Deviation between the calculated viscosity from Mao and Duan14 and that from eq 2.

Table 3. Coefficients of Eq 3 i

a

b

0 1

7.632609119 × 1002 −9.46077673946 × 1003

−1.047187396332 × 1004 3.68325597 × 1001

simulation of CO2 flows). We have discussed this in more detail in our recent study.4−6

3. VISCOSITY OF H2O + NaCl Recently Mao and Duan15 have done very nice viscosity modeling work for brine (H2O + NaCl). Their model covers a P−T range up to 1000 bar and 350 °C, respectively, and an ionic strength of up to 6.0 molality. Their formula can reproduce the literature values within a 1% deviation. However, in their model they have used IAPWS9728 to calculate water density. Instead, to reduce the number of parameters for efficient computation of water density, we recommend the equation given below following the excess Gibbs energy function:27

Figure 3. Deviation between experimental data and calculated results by eq 4. Parts a and b show comparison with the data from Kumagai et al.,29 and part c shows comparison with the data from Bando et al.30.

(2)

Parts a an b of Figure 2 show these comparisons for two different temperatures, 30 and 100 °C, and different molalities of NaCl. From this figure we can also observe that deviation increases (∼0.1%) at higher temperatures and there is no variation due to changing molality. The proposed model is around 2 times faster (8 ms vs 16 ms) than Mao and Duan’s15 approach.

Parameters of eq 2 are predicted by regressing generated calculations from IAPWS97; with this modification of Mao and Duan’s15 formulation we reproduce their values with a maximum 0.1% deviation. P is in MPa. Table 2 shows the parameters’ values.

4. VISCOSITY OF H2O + CO2 Kumagai et al.29 measured the viscosity of water containing up to 4.8% (by weight) CO2 at pressures up to 400 bar and

3

ρH O = a0 + 2

2

∑ bi10c T + ∑ diP i i

i=1

i=1

5332

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temperatures from 0 to 50 °C. They presented their experimental results only in graphical form, and therefore, although there is chance of having uncertainty in picking exact numeric value from graphs, we did so for our modeling purposes, yielding the following equation

by Bando et al.30 The authors'29 study clearly reveals that, for temperatures greater than 25 °C, the effect of pressure on the viscosity of water with dissolved CO2 is nil and, as the temperature increases (>50 °C), the effect of CO2 dissolution becomes less important.

2

μr = 1 +

i ∑i = 1 aixCO 2 1 ∑i = 0 biT i

5. VISCOSITY OF H2O + NaCl + CO2 We have found three data sources where the effects of CO2 dissolution on brine viscosity were considered.30−32 The study by Kumagai and Yokoyama32 is not relevant here because their temperature range is too low (