Название | Structural Analysis and Synthesis |
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Автор произведения | Stephen M. Rowland |
Жанр | География |
Серия | |
Издательство | География |
Год выпуска | 0 |
isbn | 9781119535485 |
4 Draw a line from the intermediate elevation point to equivalent scaled elevation on the highest to lowest line. This is the strike line. In Figure 2.10c, there are two points, B and B′, of equal elevation lying in the plane of the bed and defining the strike of the plane. The structure‐contour line B–B′ is drawn, and the strike is measured with a protractor to be 048 (N48°E).
5 A series of strike lines can now be drawn on the map parallel to the strike line at selected regular elevations. Use the scaled line from highest to lowest elevation to determine the structural contours to be drawn (Figure 2.10d). The spacing (d) between the structure contours of chosen elevation increments is replicated across the map to complete the structure contour map (See Figure 2.13a).
6 The spacing (d) reflects the angle of dip and the dip direction is perpendicular to strike in the direction of lower elevations. The dip angle can be determined trigonometrically like slope on a topographic map as shown for Figure 2.10 and 2.13a:
More commonly, three‐point problems are applied to well data. The procedure is the same as described for surface exposures except the elevations used in the analysis are from depth below the surface. The elevation for each well is the drilling depth subtracted from the surface elevation to yield an elevation relative to sea level, the datum. There is a difference between solid elements such as beds, faults, or dikes and the water table which is commonly independent of them. The dip angle and its direction show the direction of groundwater movement and possibly some indication of relative velocity.
Figure 2.10 Solution of a three‐point problem using a combination of graphical and trigonometric techniques. (a) Three coplanar points (A, B, and C) on a topographic map. (b) Connect by lines to make a triangle. Locate of a fourth point, B′ on the AC line, at the same elevation as point B. (c) Line B–B′ defines the strike of the plane. (d) Dip‐direction line perpendicular to the line B–B′; dip angle determined using Step 6.
Points A, B, and C in Figure P2.3 are oil wells drilled on a level plain, and all of the wells tap the same oil‐bearing sandstone. The depth (not the elevation!) of the top of this sandstone in each well is as follows: A = 5115 ft, B = 6135 ft, and C = 5485 ft.
1 Determine the attitude of the sandstone.
2 If a well is drilled at point D, at what depth would it hit the top of the sandstone?
Drawing a Topographic Profile
Topographic profiles are the first step in drawing a geologic cross section. The profiles show the relief at the earth's surface along the top of the geologic structure section. Usually you will have to construct your own topographic profile. Cross sections must be drawn on topographic profiles with no vertical exaggeration. The technique for drawing a topographic profile is as follows:
1 Draw the section line on the map (Figure 2.11a).
2 Lay the edge of a piece of paper along the section line, and mark and label on the paper each contour, stream, and ridge crest (Figure 2.11b).
3 Scale off and label the appropriate elevations on a piece of graph paper (Figure 2.11c). Graph paper with 10 or 20 squares per inch is ideal for 7.5‐minute quadrangle maps because the scale is 1 in = 2000 ft. Notice that the map scales on Figures 2.11a and 2.11b are the same as the vertical scale on Figures 2.11c and 2.11d. It is very important that the vertical and horizontal scales are the same on structure sections. This is a very common oversight. If the scale of the structure section is not the same as the scale of the map then the dips cannot be drawn at their normal angle.Figure 2.11 Technique for drawing a topographic profile. (a) Draw section line on map. (b) Transfer contour crossings, streams, and other features to another sheet of paper. (c) Transfer points to proper elevation on cross section sheet. (d) Connect points in a way that reflects the topographic subtleties recorded on the map.
4 Lay the labeled paper on the graph paper and transfer each contour, stream, and ridge crest point to the proper elevation on the graph paper (Figure 2.11c).
5 Connect the points (Figure 2.11d).
Drawing Cross Sections of Structure Contour Maps
A geologic cross section can now be added to the topographic profile. The procedure is essentially the same as the topographic profile except structure contours are used instead of topographic contours. This is a very simple procedure for planar features because they will appear as straight lines and, unlike complex topography, only two points are needed to define a straight line.
1 Construct a topographic profile (Figure 2.12).
2 Lay the edge of a piece of paper along the section line, and mark and label on the paper at least two structural contour elevations for each contact.
3 Lay the labeled paper on the graph paper and transfer each structure contour point chosen to the proper elevation on the graph paper/profile (Figure 2.12).
4 Connect the points and draw the planar features using a ruler (Figure 2.12).
Determining Outcrop Patterns with Structure Contours
If an important planar horizon is exposed in three places on a topographic map as in Figure 2.13a, its outcrop pattern can be determined on a topographic map. This is done by using the three‐point solution and locating the intersections of the structure contours with the topographic contours. This is accomplished using the following technique:
1 Draw