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Publication numberUS2880969 A
Publication typeGrant
Publication dateApr 7, 1959
Filing dateJun 1, 1955
Priority dateJun 1, 1955
Publication numberUS 2880969 A, US 2880969A, US-A-2880969, US2880969 A, US2880969A
InventorsWilliams Philip S
Original AssigneeJersey Prod Res Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Apparatus for obtaining unaltered cores
US 2880969 A
Abstract  available in
Images(1)
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Claims  available in
Description  (OCR text may contain errors)

April 7, 1-959 AVMMA P. S. WILLIAMS APPARATUS FOR OBTAINING UNALTERED CORES Filed June 1, 1955 Philip S. Williams 5,7101} Attorney Inventor United States Patent APPARATUS FOR OBTAINING UNALTERED CORES Philip S. Williams, Tulsa, Okla., assignor, by mesne assignments, to Jersey Production Research Company Application June 1, 1955, Serial No. 512,533

4 Claims. (Cl. 255-72) The present invention is concerned with an improved method for obtaining uncontaminated cores from subterranean formations. The invention is more specifically concerned with a method and apparatus for obtaining ,an uncontaminated core sample from formations containing hydrocarbon constituents at the bottom of a bore hole or well which penetrates the earths substrata. The method and apparatus are particularly characterized by the fact that the core sample may be obtained without employing drilling mud which on occasions tend to seriously contaminate and thus impair the value of the core sample. The method and apparatus are further characterized by the fact that the core sample may be continuously maintained under substantially ambient formation conditions; and that the core is sealed immediately after it is cut, thus preventing the loss of connate fluids therefrom. The invention is especially adapted for the coring of formations that are non-flowing and are open to the atmosphere.

One problem that is encountered in the search for oil is that of obtaining reliable samples of oil bearing formations that lie beneath the surface of the earth. The problem has become one of particular importance in view of the ever increasing use of secondary recovery methods for obtaining additional oil from subterranean oil reservoirs that have ceased primary production. It is essential, before initiating a secondary recovery procedure in any such reservoir, to have as much information as possible about the structure, the fluid content, the pore volume, the permeability, etc. of the reservoir. Such information is extremely valuable in determining whether the reservoir formation is susceptible to successful exploitation using secondary recovery techniques and just which particular techniques should preferentially be utilized.

In line with the growing emphasis on secondary recovery programs, many petroleum producers are conducting extensive analyses of old reservoirs and fields that have lost their reservoir pressures and have been abandoned. In an effort to evaluate these old reservoirs and fields, and in order to determine whether a secondary recovery procedure can be successfully applied to them, the producers are conducting extensive testing programs. One technique has been to drill and sample the bottoms or side walls of old wells that were originally producing wells associated with a reservoir or field. However, in many instances the samples derived by this technique are not truly representative of the field or reservoir as a whole. This is due in part to the fact that it is very diflicult to determine the true fluid content of reservoir rock. Accordingly, it has become more and more the established practice to drill entirely new holes from the earths surface down to an oil bearing formation and to obtain samples of the formation directly from these new holes. Conventional drilling and coring methods such as rotary and cable tool have been employed for this purpose. In all of these types of drilling it is conventional to use air or gas or at least a small amount of drilling 2 mud, water or other drilling fluid in the bottom of th hole.

However the presence of the drilling mud, water or other drilling liquid in a hole still constitutes an undesirable feature when sampling a reservoir of the type described for the reason that the hydrostatic pressure and wetting effects of even this small amount of liquid seriously interferes with the reliability of the core samples that are obtained. It is accordingly an object of the present invention to provide an apparatus and method for obtaining reservoir core samples wherein the samples need not be subjected to a drilling liquid of any kind. It is a further object of the invention to provide means for coring a formation in such a manner that the core sample suffers little exposure to material that may be a source of contamination. It is a particular object of the present invention to provide means for isolating a core .sample within the coring apparatus so that connate fluids are sealed within the sample. It is further a particular object of the invention to provide a coring method and apparatus wherein a core sample is sealed as it is cut to protect it from contaminating substances.

These objectives are realized in accordancewith th present invention by the utilization of a core drill assembly that is at least partially filled with a core sealing agent and which is arranged to receive the core. As the core is cut by the core bit and enters the core barrel, the sealing agent is displaced and is extruded and distributed over the outer surface of the core. The sealing agent acts to seal the pores of the core sample and thereby prevents fluids from escaping from the sample. The film of sealing agent additionally prevents contaminating substances from penetrating within the sample. As a core sample is cut by the coring apparatus, the sample forces its way into the core barrel with the result that sealing agent is displaced or extruded from within the core barrel and is deposited over the outer surface of the core sample.

The present invention may be more fully understood by reference to the drawing in which:

Fig. lillustrates a longitudinal section of one embodiment ofa coring apparatus; and,

Fig. 2 illustrates a frangible disc in the lower portion of the inner core barrel of the apparatus shown in Fig. 1.

Referring specifically to the drawing, a core barrel assembly 1 is shown disposed in the bottom of bore hole 2 in the earths substrata. The core barrel assembly is attached by suitable means to the lower end of tubing or drill pipe 3. The core barrel assembly comprises an outer cylindrical element 4 which is attached at one end to the lower end of the drill stem and contains at its lower edges suitable cutting bit elements such as cone elements 5. The core assembly also contains an inner core receiving barrel 6 which is preferably rifled on the inner bore .to prevent sticking of sealing material which is positioned within the inner barrel. The inner barrel is swiveled at bearing 7 so as the drill stem 3 rotates along with the outer barrel 4 the inner core receiving barrel will reimain stationary. In accordance with one preferred adaptation of the present invention the sealing material within the inner barrel is sealed by means of a frangible disc 14 positioned at its lower end.

Thus, as a coring operation starts, the outer core barrel will rotate and cut an annulus about the core as it along with the non-rotating inner core receiving barrel will move downwardly. In accordance with a preferred adaptation of the invention the viscous material placed within the core receiving barrel is maintained in position by a frangible disc 14. As the core assembly moves downwardly the frangible disc will be fractured and the viscous material 10 within the core receiver will be forced or extruded into the area 11 between the core and the inner surface of the core receiving barrel. Under certain circumstances it may be desirable to circulate mud downwardly in the drill stem 3 through port 8 and downwardly in the area 12' between the. inner core receiving barrel and the outer rotating core cutting barrel. This circulat ing mud will move through suitable ports in the bit and upwardly in the area 13 between the rotating outer barrel and the bore hole wall. However, in most instances it is'desirable not to circulate mud but to secure and seal oh the core without its use.

Thus as the core moves upwardly within the inner barrel the sealing material is extruded around the core as it enters the barrel. Excess sealing material is removedthrough the ports of the bit and flows into area 13.

While a frangible disc has been described with respect to the drawing, it is to be understood that the sealing material may be made sufiiciently viscous so as not to be fiowable but which can be extruded as the core receiving barrel moves downwardly in the annulus about the core. It is also within the scope of the present invention to use as a sealing agent a very highly viscous membrane at the lower end of the inner core prior to coringand to have this high viscous membrane of sufiicient thickness serve to hold in place a less viscous and thermo setting sealing material.

Insofar as the choice of sealing agent is concerned, it

is necessary that this material flow readily under the ambient conditions that prevail during a coring operation and. that it be substantially chemically inert toward the apparatus as well as toward the core sample. While it is notv essential that the sealing agent be non-wetting, it is preferred that it be so, so that it would not have a tendency to stick to, or penetrate the core sample. It is additionally preferred that the agent possess lubricating qualities soas to reduce the amount of friction that customarily exists between the core and the inner core barrel. It is further preferred that the agent be substantially chemi cally inert toward the drilling fluid as well as toward water and the hydrocarbons that are present within the core-sample.

In addition to the above characteristics, it is desirable that the sealing agent be of a character to form a film over the surface of acore sample which effectually seals off the surface of the sample. Suitable sealing materials may for example be a lubricant which has a viscosity of 1,000 centistokes or-higher and a specific gravity of 1 or greater. Other suitable sealing agents are for example polymeric silicones. having a viscosity above 1,000 centistokes and thermoplastic materials such as polyvinyl chloride. Other suitable materials are for example thermo plastic: materials such as. polyesters: reaction product of adipic acid and hexamethylene diamine, reaction product of ethyleneglycol and maleic anhydrid'e, and reaction product of ethylene glycol and phthalic anhydride.

Still other suitable materials are thermo setting materials such as, condensation product of cresol and formaldehyde, condensation product of furfural, and condensation product of adipic. acid and glycerol. It is within the concept of the present invention touse as sealing materials low melting metallic alloys such as alloys of lead, bismuth, tin and the like.

In general the material may be a time-setting plastic so chosen that with a reasonable weight on the bottom after coring the plastic would set up and positively encase the core. The material may be of a therrno,v plastic type which will solidify on cooling. The cooling may be accomplished by either coring with a hot tool or chillin after operation at ambient temperature.

A particularly desirable adaptation of the apparatus of the present invention is to use a material in the core receiving barrel that is frangible. Thus when the core receiving barrel is removed it can be readily broken to secure a sealed core which may be handled as desired.

While not illustrated in the drawing, it is to be understood that conventional core catchers and break off de vices as well as conventional seal off devices such as described in U. S. Patents 2,343,805 and 2,216,962 may beemployed in conjunction with the present invention.

Having described the invention, it is claimed:

l-. A core barrel for securing an uncontaminated core which comprises an outer barrel adapted to be positioned at the lower end of a string of drill pipe, a coring bit connected to the lower end of said outer barrel, an inner core receiving barrel disposed within said outer barrel, swivel means supporting said inner barrel from said outer barrel and adapted to provide relative rotational movement between said barrels, the outer surface of said inner barrel being spaced from the inner surface of said outer barrel and defining an annular space therebetween', the internal diameter of said inner barrel being slightly greater than the diameter of a core cut by said coring bit, said inner corebarrel containing a liquid viscous core sealing agent capable of forming a film over said core and means for retaining the sealing agent within said core barrel.

2. An apparatus as defined in claim 1 including a frangible disc sealingthe entrance to said inner barrel and adapted to be broken by the entrance of a core into said inner barrel.

3'. An apparatus as defined in claim 1 including a conduit providing fluid communication between the interior of said drill string and the annular space between said inner and outerbarrels.

4. An apparatus as defined in claim 1 in which the sealing agent is a time-setting plastic.

References Cited in the file of this patent UNITED STATES PATENTS 2,034,257 Hampton Mar. 17, 1936 2,146,263 Johnston Feb. 7, 1939 2,264,449 Mounce Dec. 2', 1941 2,373,323 Macready Apr. 10, 1945 2,615,680 Kjellman et al. Oct. 28, 1952 2,666,620 Welge et a1. Jan. 19, 1954 2,686,689 Pyke Aug. 17", 1954

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US2034257 *Mar 6, 1933Mar 17, 1936Hampton Core Barrel & Supply CCore barrel
US2146263 *May 31, 1938Feb 7, 1939Norris JohnstonMethod of coring to preserve fluid content
US2264449 *Apr 12, 1939Dec 2, 1941Standard Oil Dev CoMethod and apparatus for coring
US2373323 *Nov 21, 1941Apr 10, 1945Macready George AProcess and apparatus for pressure core drilling
US2615680 *Mar 29, 1948Oct 28, 1952Edmund Kallstenius Torsten KarMeans for extracting cores of soil from the ground
US2666620 *May 29, 1948Jan 19, 1954Standard Oil Dev CoOil well coring method
US2686689 *Apr 29, 1950Aug 17, 1954Douglas Pyke HerbertMethod and apparatus for retrieving junk from well bores
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3064742 *Sep 5, 1958Nov 20, 1962Jersey Prod Res CoObtaining unaltered core samples
US3112799 *Mar 9, 1960Dec 3, 1963Jersey Prod Res CoCoring fluid
US3123158 *Mar 3, 1964 sealing porous sukfaces
US3146837 *Dec 30, 1958Sep 1, 1964Jersey Prod Res CoSystem for obtaining trube core samples
US3151689 *Apr 18, 1960Oct 6, 1964Sun Oil CoApparatus for obtaining gas samples
US3158209 *Jul 30, 1962Nov 24, 1964Jersey Prod Res CoMethod of sampling underground formations
US3194326 *Aug 28, 1962Jul 13, 1965Bodine Jr Albert GSonic tool for ocean floor coring
US3324563 *Feb 15, 1965Jun 13, 1967C I M Consultants LtdCore orientation in bore hole
US3454117 *Jan 16, 1968Jul 8, 1969Exxon Production Research CoObtaining unaltered core samples of subsurface earth formations
US4071099 *Jul 19, 1976Jan 31, 1978Sun Oil CompanyMethod and apparatus for stabilizing borehole cores
US4130170 *Feb 8, 1977Dec 19, 1978Barymin Explorations LimitedProbe for use in geological surveys
US4378050 *Sep 16, 1981Mar 29, 1983Tatevosian Ruben AArrangement for full hole drilling
US4981183 *Jul 6, 1988Jan 1, 1991Baker Hughes IncorporatedApparatus for taking core samples
US5360074 *Apr 21, 1993Nov 1, 1994Baker Hughes, IncorporatedMethod and composition for preserving core sample integrity using an encapsulating material
US5482123 *Oct 25, 1994Jan 9, 1996Baker Hughes IncorporatedMethod and apparatus for pressure coring with non-invading gel
US5494119 *Jul 12, 1994Feb 27, 1996Tully; Francis X.In percussion type downhole drilling equipment
US5546798 *May 12, 1995Aug 20, 1996Baker Hughes IncorporatedMethod and composition for preserving core sample integrity using a water soluble encapsulating material
US5560438 *Mar 16, 1994Oct 1, 1996Baker Hughes IncorporatedMethod and composition for preserving core sample integrity using an encapsulating material
US6283228Dec 15, 2000Sep 4, 2001Baker Hughes IncorporatedMethod for preserving core sample integrity
US6695075 *Nov 9, 2001Feb 24, 2004Eijkelkamp Agrisearch Equipment B.V.Soil sampler
US7100707 *Jan 16, 2004Sep 5, 2006Harold HowardStabilized soil core samples and method for preparing same
US7124841 *Apr 30, 2004Oct 24, 2006Independent Administrative Institution Japan Agency for Marine-Earth Science & TechnologyCrustal core sampler and method of coring crustal core sample using the same
US7343984 *Feb 3, 2004Mar 18, 2008Independent Administrative Institution, Japan Agency For Marine-Earth Science And TechnologyCore sample collector equipped with sterilizing agent-applying mechanism and method of taking core sample
US8499856 *Apr 28, 2011Aug 6, 2013Baker Hughes IncorporatedSmall core generation and analysis at-bit as LWD tool
US8739899 *Apr 28, 2011Jun 3, 2014Baker Hughes IncorporatedSmall core generation and analysis at-bit as LWD tool
US8757293Jan 24, 2008Jun 24, 2014J. I. Livingstone Enterprises Ltd.Air hammer coring apparatus and method
US20120012392 *Apr 28, 2011Jan 19, 2012Baker Hughes IncorporatedSmall Core Generation and Analysis At-Bit as LWD Tool
US20120012393 *Apr 28, 2011Jan 19, 2012Baker Hughes IncorporatedSmall Core Generation and Analysis At-Bit as LWD Tool
EP0132020A1 *Mar 27, 1984Jan 23, 1985Diamond Oil Well Drilling Co.Method and apparatus for reducing field filter cake on sponge cores
Classifications
U.S. Classification175/226, 175/245
International ClassificationE21B25/08, E21B25/00
Cooperative ClassificationE21B25/08
European ClassificationE21B25/08