In LS-DYNA, contact energies are reported in the SLEOUT file.
Therein, four different values can be found:
The ‘Sliding Energy’ included in GLSTAT equals the sum of “sum of slave/master (SoSM)” from SLEOUT.
Note: The frictional energy is included in the sum of slave/master energy.
If friction is defind, e. g. in *CONTACT_... via FS and FD, the resulting energy can be found in the database variable frictional energy (FE). The frictional energy (FE) is already included in the slave energy (SE) and the master energy (ME) and hence also in the sum of slave/master energy (SoSM). Thus, one gets the energy needed to prevent penetration between the contact partners by subtracting the frictional energy (FE) from the sum of slave/master energy (SoSM). In the absence of friction the slave energy (SE) and the master energy (ME) should be close in magnitude but opposite in sign and the sum of slave/master energy (SoSM) should equal the stored energy.
When friction is included in a contact definition, positive contact is to be expected. Friction SHOULD result in positive contact energy. In the absence of friction, you would hope to see a small net contact energy (net = sum of slave side energy and master side energy). Small is a matter of judgement — 10% of peak internal energy might be considered acceptable for contact energy in the absence of contact friction.
Abrupt increases in negative contact energy may be caused by undetected initial penetrations. Care in defining the initial geometry so that shell offsets are properly taken into account is usually the most effective step to reducing negative contact energy. Refer to sections 23.8.3 and 23.8.4 in the LS-DYNA Theory Manual (May 1998) for more information on contact energy.
Negative contact energy sometimes is generated when parts slide relative to each other. This has nothing to do with friction. I’m speaking of negative energy from normal contact forces and normal penetrations. When a penetrated node slides from its original master segment to an adjacent though unconnected master segment and a penetration is immediately detected, negative contact energy is the result.
If internal energy mirrors negative contact energy, i.e., the slope of internal energy curve in GLSTAT is equal and opposite that of the negative contact energy curve, it;s possible that the problem is very localized with low impact on the overall validity of the solution. You may be able to isolate the local problem area(s) by fringing internal energy of your shell parts (Fcomp > Misc > internal energy in LS-PrePost). Hot spots in internal energy usually indicate where negative contact energy is focused.
If you have more than one contact defined, the sleout file (*DATABASE_SLEOUT) will report contact energies for each contact and so the focus of the negative contact energy investigation can be narrowed.
SOFT=1 and IGNORE=2 (Optional Card C).SOFT=2 on Optional Card A. SOFT=2 is also referred to as segment-based contact and so is not applicable to any NODE_TO_SURFACE type contacts. Two important companion variables to SOFT=2 are SBOPT and DEPTH.Two important companion variables to SOFT=2 are SBOPT and DEPTH.The specifics of your model may dictate that some other approach be used.