Internal Identifiers

The data in the background files are identified by a so-called identifier number. With the help of the identifier number and the SPRING-interface DTNLIB, each module knows how to store and read the data, how to plot the data, and their meaning.

The user notices the internal data management with identifier numbers only in the batch files for the plot generation or the data export: These files define the data to be plotted with the help of identifiers. The following tables contain all identifying information.

One line of a table contains the following information:

column 1: identifier number (< 1000)

column 2: class: the data class manages the storage and reading procedures:

k = node wise data

K = node wise data for the nodes of the topmost layer (3D-model)

e = element wise data

E = data for the elements of the topmost layer (3D-model)

r = data along a polyline or a group of nodes

R = data for the nodes/elements of the topmost layer (3D-model)

1 = 1D fracture data

2 = 2D fracture data

x = for nodal / elemental data

without class = for data without direct meaning, e.g. index arrays

column 3: description

Model data after model checking

Identifier number	class	description
2D mesh data:
1	k	Mesh boundary
2	k	Node numbers
3	e	Element numbers
4	k	x-,y-coordinates
3D mesh data:
11	k	3D mesh boundary
13	k	z-coordinates
Fracture description:
22	1	1D fracture numbers
23	1	1D fracture aperture
24	1	1D fracture thickness
26	2	2D fracture numbers
27	2	2D fracture aperture
Plot data:
32	x	Markers
33	k	text at nodes
34	e	text at elements
Internal data:
45	k	Layer number for nodes
46	e	element numbers in the layers beneath
47	e	Layer number for elements
Analysis data:
51	R	Control lines
52	k	PRAN-nodes
53	r	Mass balance nodes
54	E	Mass balance elements
55	r	Group of mass balance nodes with numbers
56	e	Group of mass balance elements with numbers
Parameters:
61	e	permeabilities (m/time unit)
62	e	vertical permeabilities (m/time unit)
63	e	Storage coefficient
64	k	Porosities
65	e	Dispersivities
67	k	Storage coefficients
68	1	1D fracture dispersivities
69	2	2D fracture dispersivities
70	k	Zones for K_d(XTRA)
Calibration data:
71	e	minimum permeability (m/time unit)
72	e	maximum permeability (m/time unit)
73	k	initial potential head
75	e	Permeability zones
76	k	Zones for the storage coefficient
77	r	Zones for the leakage at nodes
78	e	Van-Genuchten-zones
79	e	Van-Genuchten-parameters
80	e	Initial saturation
Geology:
81	E	Initial thickness
82	E	Lower boundary
83	E	Upper boundary
84	K	Thickness of the impermeable layer
85	K	Ground level
86	K	Terrain settings as a result of subsurface mining
87	E	Maximum thickness
boundary conditions for potential equation:
91	k	boundary potential head
92	r	equal potential head
93	k	Leakage coefficients (m²/nodes/time unit)
94	e	Leakage coefficients (m²/m²/time unit),(ms)
95	r	Leakage coefficients (m/time unit)
96	k	receiving water course level
97	r	maximum exfiltration rates (m³/m/time unit)
98	r	maximum infiltration rates (m³/m/time unit)
99	e	maximum exfiltration rates (m³/m²/time unit)
100	e	maximum infiltration rates (m³/m²/time unit)
101	r	seepage surface node
102	k	Leakage coefficients (m²/node/time unit)
103	k	maximum exfiltration rates (m³/node/time unit)
104	k	maximum infiltration rates (m³/node/time unit)
105	e	Leakage coefficients (m²/element/time unit)
106	e	maximum exfiltration rates (m³/el./time unit)
107	e	maximum infiltration rates (m³/el./time unit)
108	k	break hight
109	k	Ratio of the leakage coefficient EXF/INF
110	e	Ratio of the leakage coefficient EXF/INF
Source data:
111	E	recharge rate (m³/El./time unit)
112	k	Sinks and sources (m³/node/time unit)
113	r	Boundary in- and outflow (m³/time unit)
boundary and initial conditions transport equation:
120	k	Inflow rate (per s)
121	k	defined concentrations
122	k	Source concentrations
123	k	Initial concentrations
124	k	defined concentrations (XTRA)
125	k	Source concentrations (XTRA)
126	k	Initial concentrations (XTRA)
127	k	Inflow rate (per s) (XTRA)
General data:
131	k	general nodewise data
132	e	general elementwise data
155	k	Cavity nodes
156	k	Cavity water level
157	k	Cavity addition volume

Steady state results or interpolation results after a calibration, calculation of a steady state flow or an interpolation:

Identifier number	class	description
results of the potential equation / concentration equation:
201	k	Potential heads
202	e	Potential heads at element centers
203	k	Concentrations
204	e	Velocities
205	e	Velocities
206	k	Concentrations (XTRA)
208	1	Velocity of 1D fractures
209	2	Velocity of 2D fractures
further results:
210	k	Seepage rates (m³/node/time unit)
211	k	Mass flow rates (m³/node/time unit)
212	R	Control line rates (m³/time unit)
213	k	Leakage rates (m³/node/time unit)
214	e	Leakage rates (m³/element/time unit)
215	K	distance between ground level and groundwater level
216	k	Saturation
218	E	Changed lower boundary
219	E	Iterated thickness
220	K	Iterated nodewise thickness
Path line data:
221		Path lines (2D)
222		Path lines (3D)
Peclet numbers:
225	e	Peclet number longitudinal
226	e	Peclet number transversal
Spezial results of the calibration:
231	e	iterated permeability (m/time unit)
232	e	iterated vertical permeability (m/time unit)
Interpolation results:
240	K	Interpolated node data
241	E	Interpolated element data

Transient results:

Identifier number	Class	Description
Time steps:
300		Date/time, time unit, referred date
results of the potential equation / concentration equation: last time step:
301	k	Potential heads
302	e	Potential heads at element centers
303	k	Concentrations
304	e	Velocities (2D)
305	e	Velocities (3D)
306	k	Concentrations (XTRA)
309	2	Velocities of 2D fractures
further results: last time step:
310	k	Seepage rates (m³/node/time unit)
311	k	Mass flow rates (m³/node/time unit)
312	R	Control line rates (m³/time unit)
313	k	Leakage rates (m³/node/time unit)
314	e	Leakage rates (m³/element/time unit)
315	K	distance between ground level and water table
316	k	Saturation
Path line data:
321		Path lines (2D)
322		Path lines (3D)
Peclet numbers/Courant numbers:
325	e	Peclet numbers longitudinal
326	e	Peclet numbers transversal
327	e	Courant numbers
results of the potential equation / concentration equation: time-dependent:
400	k	Drawdown z-coordinates
401	k	Potential heads
403	k	Concentrations
404	e	Velocities (2D)
405	e	Velocities (3D)
406	k	Concentrations (XTRA)
409	2	Velocities of 2D fractures
further results: time-dependent:
410	k	Seepage rates (m³/node/time unit)
411	k	Mass flow rates (m³/node/time unit)
412	R	Control line rates (m³/time unit)
413	k	Leakage rates (m³/node/time unit)
414	e	Changed lower boundary
results as a function of time:
450	k	z-coordinates
451	k	Potential heads
453	k	Concentrations
456	k	Concentrations (XTRA)
Transient input data:
470	K	terrain settings as a result of subsurface mining
471	k	Defined potential heads
472	k	Receiving water course level
473	E	Recharge rates (m³/element/time unit)
474	k	Sinks and sources (m³/node/time unit)
475	k	Defined concentrations
476	k	Source concentrations

Results of the data export

Identifier number	Class	Description
523		Stream lines

Data of the inverse modelling

Identifier number	Class	Description
steady state calculation:
601	k	Potential heads / permeabilities (hori.)
602	k	Potential heads / permeabilities (vert.)
603	k	Potential heads / storage coefficients
604	k	Potential heads / nodewise leakage
611	k	Mass flow rate / permeabilities (hori.)
612	k	Mass flow rates / permeabilities (vert.)
613	k	Mass flow rates / storage coefficients
614	k	Mass flow rate / nodewise leakage
transient calculation:
651	k	Potential heads / permeabilities (hori.)
652	k	Potential heads / permeabilities (vert.)
653	k	Potential heads / storage coefficients
654	k	Potential heads / nodewise leakage
661	k	Mass flow rates / permeabilities (hori.)
662	k	Mass flow rates / permeabilities (vert.)
663	k	Mass flow rates / storage coefficients
664	k	Mass flow rates / nodewise leakage

Information of the file xsusi.kenn