Ammunition and explosives – Blasting – Patterned blasting
Reexamination Certificate
2000-07-17
2003-11-25
Nelson, Peter A. (Department: 3641)
Ammunition and explosives
Blasting
Patterned blasting
C149S077000
Reexamination Certificate
active
06651564
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to the field of geophysical surveying. More particularly, it concerns seismic methods and geophysical survey systems for petroleum and gas exploration that rely on an explosive seismic energy source that comprises an oxidizable metal material.
2. Description of Related Art
Seismic geophysical surveys are used in petroleum and gas exploration to map the following: stratigraphy of subterranean formations, lateral continuity of geologic layers, locations of buried paleochannels, positions of faults in sedimentary layers, and basement topography. Such maps are deduced through analysis of the nature of reflections and refractions of generated seismic waves from interfaces between layers within the subterranean formation.
A seismic energy source is used to generate seismic waves that travel through the earth and are then reflected by various subterranean formations to the earth's surface. As the seismic waves reach the surface, they are detected by an array of seismic detection devices, known as geophones, which transduce waves that are detected into representative electrical signals. The electrical signals generated by such an array are collected and analyzed to permit deduction of the nature of the subterranean formations at a given site.
Seismic energy sources that have been used in geophysical survey methods for petroleum and gas exploration include impact sources, gun sources, vibratory sources and explosives. The nature of output seismic energy depends on the type of seismic energy source that was used to generate it.
Fundamentally, an impact source is a weight striking the surface of the earth directly or impacting a plate placed on the earth's surface, yielding seismic energy. A weight-drop is an example of the former type of impact source. While impact sources tend to be relatively inexpensive and simple to operate and maintain, their principal disadvantage is that they are inefficient at producing seismic energy useful for geophysical survey of deeper layers. Impact sources yield a relatively high proportion of low frequency, surface waves and output less seismic energy than other seismic energy sources.
Gun sources, like impact sources, transfer kinetic energy into seismic energy. They rely on the sudden, powerful release of a charge of pressurized gas, usually compressed air from an air gun, to generate seismic waves. Gun sources have an advantage over impact sources in that they produce more seismic energy than is possible with simple impact sources. The seismic energy generated by gun sources also tends to be of higher-frequency than that imparted by impact sources, and this helps to minimize surface wave generation and improve resolution. However, gun source equipment tends to be more bulky and expensive than simple impact sources.
Vibratory sources are also used as seismic energy sources in geophysical survey methods. Two categories of vibratory sources include those that generate seismic waves originating at the surface and those that generate seismic waves that emanate from downhole. One mechanical-hydraulic vibratory source, the Vibroseis truck, is specially designed to place all of its weight onto a large platform which vibrates. This vibration, in turn, produces seismic waves in the subterranean formation. Vibroseis trucks have been used extensively in geophysical survey methods, not just for the petroleum and gas exploration, but also for studying the evolution and development of specific geological structures (e.g. the Rocky Mountains) and fault lines. Vibratory sources tend to produce highly repeatable seismic energy. The nature of the energy delivered into the ground by vibratory sources, its amount, duration, and time of delivery, can be tightly controlled and therefore the seismic energy generated tends to be very reproducible, which is a benefit. However vibratory sources are often not suited to certain types of terrain. For example if the ground is very soft, it can be difficult to use Vibroseis trucks as a seismic energy source.
Another type of seismic energy source used in geophysical survey relies on explosives. Explosive seismic energy sources used in petroleum and gas exploration on land rely on the explosion of material placed within a subterranean formation to generate seismic waves. Typically, a hole is drilled in the ground, the explosive is placed in the hole, and backfill is piled on top of the explosive, prior to initiating the explosion. Compared on a pound for pound basis to gun sources and impact sources, explosive sources impart the highest amount of seismic energy into the ground. Explosive seismic energy sources currently being used in geophysical survey methods generally produce waves of very high frequency. They are often used when the ground conditions are such as to prevent the effective use of impact or gun sources (i.e. when the ground is extremely soft).
Many explosives used in seismic energy sources generate high gas volumes. This is a useful property in mining for moving rock, but is undesirable in seismic exploration, because it decreases the amount of usable seismic energy that is generated. Explosives that produce high volumes of gas cause much of the energy of the explosion to be lost as expanding gases force backfilled material up the borehole into which the explosive was placed. Thus, less of the energy generated by the explosion is transferred into the subterranean formation than would be theoretically possible if less energy was lost to expansion of generated gases. In addition; the sudden expansion of a large volume of gas can cause permanent deformation of the subterranean formation itself.
At present, the demand for seismic exploration methods that generate sharper energy pulses, which can result in higher resolution images, has led to sacrificing the generation of low frequency seismic waves. This loss of low frequency waves compromises the ability to image deeper targets (e.g., >3 seconds). While Vibroseis has been used successfully in mapping deeper targets, it has been difficult to achieve the same quality of results using explosive seismic sources. This presents a significant problem when there is a need for mapping deeper subterranean formations but the ground conditions are not suited to Vibroseis. In the past, the response has been to drill deeper boreholes and use more explosive to achieve the desired results at such difficult mapping sites. Both drilling deeper and using more explosive substantially increase the cost of subterranean mapping of a particular site.
There is a need for improved seismic methods and geophysical survey systems that rely on explosive compositions that convert a higher percentage of the potential energy in the explosive composition into seismic energy . There is also a need for improved methods and systems that efficiently generate low frequency seismic waves when needed. Furthermore, it would be advantageous to be able to use shallower boreholes and less explosive to achieve the necessary level of data resolution for geophysical survey.
SUMMARY OF THE INVENTION
This invention provides improved seismic methods and geophysical survey systems that are well suited for petroleum and gas exploration, but could be used for other purposes as well.
One aspect of the invention is a seismic method that comprises the steps of generating seismic waves by exploding an explosive composition in a subterranean formation, and detecting the seismic waves and/or reflections thereof with seismic detectors. The explosive composition used in this method comprises a first explosive material and an oxidizable metal material. The explosive composition can suitably be placed in a borehole within the subterranean formation, and covered with backfill before being exploded. The explosive composition preferably is essentially nitrogen-free (e.g., the nitrogen content of the explosive composition is less than about 1 wt %, preferably less than about 0.1 wt %).
In one embodiment of the invention, the first e
Brooks James E.
Tite Glen-Allan
Voreck Wallace E.
Figatner David S.
Nelson Peter A.
Schlumberger Technology Corporation
Williams, Morgan & Amorson
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