Distinguish Background From Effective CTFs

SCON[0] holds the effective connection transmissibility factor, including pressure dependent multipliers such as those arising from rock compaction. This commit distinguishes SCON[0] from SCON[11], with the latter holding the background from geometry and "static" multipliers (WPIMULT, WELPI).
2023-11-13 10:48:26 +01:00 · 2023-11-13 10:48:26 +01:00 · 16ad535f7f
commit 16ad535f7f
parent 1129e95a16
3 changed files with 19 additions and 12 deletions
--- a/opm/output/eclipse/VectorItems/connection.hpp
+++ b/opm/output/eclipse/VectorItems/connection.hpp
@ -44,7 +44,7 @@ namespace Opm { namespace RestartIO { namespace Helpers { namespace VectorItems

    namespace SConn {
        enum index : std::vector<float>::size_type {
-            ConnTrans    =  0, // Connection transmissibility factor
+            EffConnTrans =  0, // Effective connection transmissibility factor (incl. ROCKTAB &c)
            Depth        =  1, // Connection centre depth
            Diameter     =  2, // Connection diameter

@ -54,7 +54,7 @@ namespace Opm { namespace RestartIO { namespace Helpers { namespace VectorItems
            CFDenom = 6,    // Denominator in connection transmissibility
                            // factor expression

-            item12       = 11, // Connection transmissibility factor
+            ConnTrans = 11, // Connection transmissibility factor

            SegDistEnd   = 20, // Distance to end of connection in segment
            SegDistStart = 21, // Distance to start of connection in segment
--- a/src/opm/output/eclipse/AggregateConnectionData.cpp
+++ b/src/opm/output/eclipse/AggregateConnectionData.cpp
@ -180,7 +180,7 @@ namespace {
                return static_cast<float>(units.from_si(u, x));
            };

-            sConn[Ix::ConnTrans] =
+            sConn[Ix::EffConnTrans] = sConn[Ix::ConnTrans] =
                scprop(M::transmissibility, conn.CF());

            sConn[Ix::Depth]    = scprop(M::length, conn.depth());
@ -193,8 +193,6 @@ namespace {

            sConn[Ix::CFDenom] = conn.ctfProperties().peaceman_denom;

-            sConn[Ix::item12] = sConn[Ix::ConnTrans];
-
            if (conn.attachedToSegment()) {
                const auto& [start, end] = *conn.perf_range();
                sConn[Ix::SegDistStart] = scprop(M::length, start);
@ -223,8 +221,15 @@ namespace {
                return static_cast<float>(units.from_si(u, x));
            };

-            sConn[Ix::item12] = sConn[Ix::ConnTrans] =
+            sConn[Ix::EffConnTrans] = sConn[Ix::ConnTrans] =
                scprop(M::transmissibility, xconn.trans_factor);
+
+            // xconn.trans_factor == CTFAC == CF * rock compaction.  Divide
+            // out the rock compaction contribution to infer the "real"
+            // connection transmissibility factor.  No additional unit
+            // conversion needed since the rock compaction effect (keyword
+            // ROCKTAB) is imparted through a dimensionless multiplier.
+            sConn[Ix::ConnTrans] /= xconn.compact_mult;
        }
    } // SConn

--- a/tests/test_AggregateConnectionData.cpp
+++ b/tests/test_AggregateConnectionData.cpp
@ -502,6 +502,7 @@ END
                    c.pressure = 215.0;
                    c.index = connections[i].global_index();
                    c.trans_factor = connections[i].CF();
+                    c.compact_mult = 0.875;

                    const auto& global_index = connections[i].global_index();
                    sum_state.update_conn_var("PROD", "CWPR", global_index + 1, qw * (i + 1));
@ -543,6 +544,7 @@ END
                    c.pressure = 218.0;
                    c.index = connections[i].global_index();
                    c.trans_factor = connections[i].CF();
+                    c.compact_mult = 0.987;

                    const auto& global_index = connections[i].global_index();
                    sum_state.update_conn_var("WINJ", "CWIR", global_index+ 1, qw*(i + 1));
@ -683,12 +685,12 @@ BOOST_AUTO_TEST_CASE(Declared_Connection_Data)
        const auto& sconn = amconn.getSConn();
        int connNo = 1;
        auto i0 = (connNo - 1) * ih.nsconz;
-        BOOST_CHECK_CLOSE(sconn[i0 + Ix::ConnTrans], 2.55826545, 1.0e-5); // PROD - conn 1 : Transmissibility factor
+        BOOST_CHECK_CLOSE(sconn[i0 + Ix::EffConnTrans], 2.55826545, 1.0e-5); // PROD - conn 1 : Effective transmissibility factor
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::Depth], 7050., 1.0e-5); // PROD - conn 1 : Centre depth
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::Diameter], 0.20, 1.0e-5); // PROD - conn 1 : diameter
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::EffectiveKH], 1581.13879, 1.0e-5); // PROD - conn 1 : effective kh-product
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::CFDenom], 4.37696314, 1.0e-5);
-        BOOST_CHECK_CLOSE(sconn[i0 + Ix::item12], 2.55826545, 1.0e-5); // PROD - conn 1 : Transmissibility factor
+        BOOST_CHECK_CLOSE(sconn[i0 + Ix::ConnTrans], 2.55826545 / 0.875, 1.0e-5); // PROD - conn 1 : Transmissibility factor
        BOOST_CHECK_CLOSE(
            sconn[i0 + Ix::SegDistEnd], 130., 1.0e-5); // PROD - conn 1 : Distance to end of connection in segment
        BOOST_CHECK_CLOSE(
@ -698,12 +700,12 @@ BOOST_AUTO_TEST_CASE(Declared_Connection_Data)
        // Well no 2 - WINJ well
        connNo = 3;
        i0 = ih.ncwmax * ih.nsconz + (connNo - 1) * ih.nsconz;
-        BOOST_CHECK_CLOSE(sconn[i0 + Ix::ConnTrans], 2.55826545, 1.0e-5); // WINJ - conn 3 : Transmissibility factor
+        BOOST_CHECK_CLOSE(sconn[i0 + Ix::EffConnTrans], 2.55826545, 1.0e-5); // WINJ - conn 3 : Effective transmissibility factor
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::Depth], 7250., 1.0e-5); // WINJ - conn 3 : Centre depth
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::Diameter], 0.20, 1.0e-5); // WINJ - conn 3 : diameter
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::EffectiveKH], 1581.13879, 1.0e-5); // WINJ - conn 3 : effective kh-product
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::CFDenom], 4.37696314, 1.0e-5);
-        BOOST_CHECK_CLOSE(sconn[i0 + Ix::item12], 2.55826545, 1.0e-5); // WINJ - conn 3 : Transmissibility factor
+        BOOST_CHECK_CLOSE(sconn[i0 + Ix::ConnTrans], 2.55826545 / 0.987, 1.0e-5); // WINJ - conn 3 : Transmissibility factor
        BOOST_CHECK_CLOSE(
            sconn[i0 + Ix::SegDistEnd], 0., 1.0e-5); // WINJ - conn 3 : Distance to end of connection in segment
        BOOST_CHECK_CLOSE(
@ -712,12 +714,12 @@ BOOST_AUTO_TEST_CASE(Declared_Connection_Data)

        connNo = 4;
        i0 = ih.ncwmax * ih.nsconz + (connNo - 1) * ih.nsconz;
-        BOOST_CHECK_CLOSE(sconn[i0 + Ix::ConnTrans], 2.55826545, 1.0e-5); // WINJ - conn 4 : Transmissibility factor
+        BOOST_CHECK_CLOSE(sconn[i0 + Ix::EffConnTrans], 2.55826545, 1.0e-5); // WINJ - conn 4 : Effective transmissibility factor
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::Depth], 7250., 1.0e-5); // WINJ - conn 4 : Centre depth
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::Diameter], 0.20, 1.0e-5); // WINJ - conn 4 : diameter
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::EffectiveKH], 1581.13879, 1.0e-5); // WINJ - conn 4 : effective kh-product
        BOOST_CHECK_CLOSE(sconn[i0 + Ix::CFDenom], 4.37696314, 1.0e-5);
-        BOOST_CHECK_CLOSE(sconn[i0 + Ix::item12], 2.55826545, 1.0e-5); // WINJ - conn 4 : Transmissibility factor
+        BOOST_CHECK_CLOSE(sconn[i0 + Ix::ConnTrans], 2.55826545 / 0.987, 1.0e-5); // WINJ - conn 4 : Transmissibility factor
        BOOST_CHECK_CLOSE(
            sconn[i0 + Ix::SegDistEnd], 0., 1.0e-5); // WINJ - conn 4 : Distance to end of connection in segment
        BOOST_CHECK_CLOSE(