DE1139453B - Method for treating wells - Google Patents

Description

Method of treating wells. The invention relates to a Method of treating wells lined with perforated casing.

When developing boreholes which are used for oil, water or gas extraction, treatment fluids are pumped into the boreholes, and the pumping in takes place through perforations in the casing of these boreholes T. In particular, liquids that open up the surrounding rock through mechanical or chemical action are suitable as treatment liquids. When such treatment fluids are pumped in, a disproportionately large proportion of the fluid, which may also be a pumpable slurry, often passes through one or a few of the numerous perforations in the casing.

The passage of a disproportionately large proportion of the treatment liquid through one or a few perforations. piping is common due to the fact that the rock formations adjacent to this or these boreholes are more permeable to the treatment liquid than the formations in the vicinity the remaining perforations.

When the treatment liquid or the pumpable slurry easily pump through one or a few perforations in the tubing it is often impossible to pump that much pumping power to the hydrostatic To keep pressure in the well so great that the treatment liquid or slurry also those perforations of the piping penetrated which are only slightly permeable or poorly permeable mountains are surrounded.

It has already been proposed to solve this problem in that at least a part of the perforations of the casing, which are in the area of well-permeable rock forinations, is partially closed when the treatment liquid is pumped in, so that the treatment liquid is also in the less permeable sections of the Rock forinations passes through the now only open openings assigned to these formations. Spherical rubber or hard core seals with a resilient outer support have been proposed to be inserted into the wellbores when fluid has been pumped through the perforations of the casing. The spherical sealing bodies were then carried along in the treatment liquid and were transported to those perforations in the casing through which larger amounts of treatment liquid passed, i.e. H. for those perforations that were in contact with well-permeable rock layers. Once such a spherical seal body was in contact with a perforation in the casing, it was held in place by the pressure of the treatment liquid, but on the other hand it was dimensioned to prevent the further passage of liquid through the perforation, even in was usually not driven into the perforation.

Nevertheless, they have used the previously known methods spherical seal body had disadvantages. One disadvantage was that every now and then yet again a sealing body in a perforation due to the high pressure inside was driven into the tubing so that this perforation was sealed forever and the performance of the probe was correspondingly reduced.

Another disadvantage of the known spherical sealing body it is that due to the high pressure which enters the unsealed perforations reaches the rock layers adjacent to the closed perforations can be.

It also brings the complete closure of one or more perforations with it that a large pressure differential between the piping to which this piping surrounding cement mantle and the rock layer arises; these Differential pressure is capable of fractures and splintering or channeling in the cement mantle. Since the pressure difference, which the piping and the cement mantle is exposed, is often very significant, it is very important Avoid local pressure differences between the piping and the Zeinentniantel.

The invention is based on the object of regulating the flow through these perforations by means of throttle bodies in the treatment of boreholes provided with perforated tubing in such a way that the perforations through which a very strong flow initially flows are reduced in their permeability, without the flow completely to prevent, so that the harmful high pressure differences cannot occur and there is no risk of the throttle body being pushed into the perforations. Based on the known method for treating boreholes lined with perforated casing by pumping fluids into the formations to be opened up while regulating the fluid flow through the perforations by means of the fluid-added throttle bodies, the invention consists in that the flow through the perforations using them only partially closing throttle bodies is reduced, but not completely prevented.

Appropriately, the passage through the throttle body is set to one value reduced by 90 to 50% of the free throughput.

The figures explain the invention. 1, it illustrates Fig. Shows a longitudinal section through a cased borehole with the necessary equipment for the Aufschließuno, adjacent layers of rock, Fig. 2 a of FIG. 1 similar longitudinal section through another arrangement in which the throttle bodies into the wellbore by a particularly for this 3 is a partial section through a packer which, above the perforations of the borehole casing, forms a tight seal between the borehole casing and the inflow string, Bores, Fig. 5 is an elevation of a spherical throttle body with a plurality of grooves or channels in its outer surface, Fig. 6 is an elevation of a porous throttle body, Fig. 7 is an elevation of a throttle body with a plurality of small protrusions on its surface.

In Fig. 1 , a borehole is shown; this is designated quite generally with the reference number 10 ; the borehole 10 starts from the earth's surface 12 and extends through one or more earth formations 14 into an earth fornation 16 which contains crude oil, gas or mixtures of gas and crude oil. A string of casing 18 extends from the surface of the earth or from a location near the surface of the earth to the bottom 20 of the borehole 10. The annulus between the casing 18 and the wall 22 of the borehole 10 is filled with a cement jacket 24. The cement niantel 24 extends, as shown, from the upper to the lower end of the borehole 10; In practice, however, it happens that a cement jacket is only provided in the area of the formation 16 , but not up to the surface of the earth 12. The casing 18 of the borehole is covered by a closure body 26 ; Lines 28 and 30 are connected to this closing body 26. The line 28 is connected to a valve 32 ; this valve 32 regularly serves as a vent line at the beginning of the well treatment according to the invention.

Let us now assume that the borehole is to be opened up by a so-called frac treatment, as shown in FIG. 1 ; the line 30 runs from the end body 26 of the well casing to a mixing vessel 34. A pump 36 is located in the line 30 near the mixing device 34. Valves 38, 40 are also provided in the line 30 between the pump 36 and the end body 26 . A throttle body insertion device (indicated generally by reference numeral 42) is connected by lines 44, 46; as a result, a short-circuit path to the pipeline 30 is formed in the region of the valve 38 .

The throttle body introduction device 42 comprises an introduction chamber 48 which is connected next to its end 50 to the line 30 via a line 46 and a valve 52 . The lower end 54 of the introduction chamber 48 is connected to the line 30 via the line 44 and the valve 56, to be precise at a point between the valves 38, 40. The throttle bodies which are used are denoted by the reference numeral 58 ; they are introduced into the introduction chamber 48 intended for them through the valve 60 of the conduit 62 ; the line 62 opens into the end 50 of the chamber 48.

The treatment liquid is stored in a container or tank 64. This container 64 is connected to the mixer 34 via the line 66, a valve 68 and a pump 70 .

Granular material (this material can be recognized in FIG. 1 at points 79), such as sand, is contained in a storage container 72 ; This storage container 72 is connected to the mixer 34 via a supply line 74 and a slide 76 .

In operation, the valves 38 and 40 are open and the pump 36 works; if valve 68 is also open and pump 70 is operating, treatment fluid 78 is pumped into the wellbore through line 30. Gas residues trapped within the tubing 18 are, if necessary, released from the tubing 18 by opening the valve 32 of the line 28. This line is connected to the closing body 26. (The valve 32 is of course to be closed when all gas has been vented.) Pressure is imparted to the treating liquid 78 within the tubing 18 by a pump 36 . The casing 18 has a plurality of perforations 80 which extend through both the casing 18 and the cement jacket 24. The pressure communicated to the treatment liquid within the piping 18 is therefore also communicated to the rock formations 16 which are in contact with the perforations 80 . The pressure increases until the formation breaks up; one or more fractures 82 arise in the formation 16, as can be seen from FIG. 1.

The rupture of the formation 16 is usually noticeable at the earth's surface 12 by a drop in pressure or by a change in the pitch of the engine noises produced by the motors driving the pump 36. An increase in the flow rate in the line 30 can also serve as an indication if the line pressure remains constant.

Once a fracture has occurred in the rock formation, the slide 76 is opened and granular material 79 is now fed from the container 72 into the mixer 34 in order to be mixed there with the treatment liquid; the treatment liquid is water, oil, acid, water thickened with a gelling agent or mixtures of these substances, for example an emulsion of oil and aqueous liquid can be used.

If the fracture conditions of the rock formation 16 are known and if the well casing 18 and the other pieces of equipment which are exposed to the high pressure during the well treatment are able to counteract the expected breaking pressures, a mixture can be used instead of the pure treatment fluid from the start are pumped in from treatment liquid and granular material. If, as described here, the pure treatment liquid is first pumped in, then the possibility of the sand precipitating is excluded; this risk would exist if the rock folmation does not break and the material cannot penetrate the rock formation.

In the course of the pumping of a mixture of treatment liquid 78 and granular material 79 into the fracture points 82 of the rock formations, it can turn out that the pressure is insufficient to force the mixture into all fracture points 82 . The reason for this is usually to be sought in that one or a few of the fracture points 82 have already expanded to such an extent that the greater part of the mixture pumped into the casing 18 reaches precisely these fracture points.

If this state occurs, the valves 56 and 52 are closed according to the invention and the valve 60 is opened; one or more throttle bodies 58 have then been introduced through the valve 60 and the line 62 into the introduction chamber 48. The valve 60 is then closed and the valves 52 and 56 are opened so that the throttles 58 can pass into the line 30 and through this into the space of the well casing. (Under certain circumstances it is advisable to partially close the valve 38 in the line 30 ; this is achieved in that the throttle bodies 58 are "shot" very quickly into the line 30. ) The throttle bodies 58 expediently have approximately the same specific weight or. - approximately the same apparent specific weight. like the mixture or liquid which is pumped into the well casing 18; This equalization of the specific weights ensures that the throttle bodies 58 flow with the mixture or with the liquid without swimming in it and without sagging through it too quickly.

When the throttle elements 58 cut in those waste the well casing reach 18, which has, the perforations 80, they are entrained by the leading to the perforations flow of the treatment liquid and attach themselves to the perforations 80, through which the mixture or the Treatment liquid passes through. The throttle bodies 58 , however, do not completely close off the flow through the respective perforations, but allow a certain amount of mixture or treatment liquid to penetrate through the throttle bodies or past them into the perforations; localized stresses on the tubing 18 are therefore avoided, and the cement jacket 24 is not subjected to any stresses as it would be if the throttle bodies 58 were to completely block the perforations. After a certain amount of liquid or mixture can still flow past the throttle bodies 58 , the fracture points closed by a throttle body are widened and expanded, but not at the expense of the remaining fracture points 82 in the less permeable parts of the rock formation 16.

Since each of the throttle bodies 58 rests against one of the perforations 80 , a pressure increase on the surface of the earth is usually detected, for example on a manometer 81 which is attached to the end part 26. The increase in pressure is due to the fact that the throughput of mixture or treatment liquid which penetrates into the rock formation 16 is lower if one proceeds from the assumption that the performance of the pump or pumps 36 before and after the throttle bodies arrive at their seats same is.

It is often necessary to insert restrictors 58 into the well casing more than once during the process of treating the wellbore . H. Whenever a pressure drop is detected in the manometer at the earth's surface 12, the flow of fluid into the fracture points 82 should be reduced in order to allow the formation or expansion of additional fracture points which are in contact with other perforations 80.

When the desired amount of mixture or treatment fluid has been pumped into the well casing 18 and when treatment is finally terminated by flushing with pure treatment fluid and the pressure within the well casing 18 is reduced, the pressure in the formations is normally greater than the pressure within the borehole; the throttles 58 are therefore lifted from their seats in the perforations 80 and either fall to the bottom of the borehole or, if they are light enough, are carried along to the surface 12 by the upward flowing liquid.

The throttle bodies 58 can have a wide variety of shapes. Some of these shapes are plotted in Figures 4-7 . The throttle body 58 a shown in Figure 4 has a spherical shape; it has a large number of small bores 84 which penetrate it. The diameter of the bores 84 is large enough to allow the mixture to be used, and in particular the granulated material, to pass through. The number of holes and their arrangement is arbitrary. It is only necessary to ensure that the bores in the throttle body 58 a are distributed in such a way that, however the throttle body 58 a rests against a perforation 80 , a mixture or treatment fluid can penetrate into the perforation 80 through one of the bores. The throttle body 58 a, and the same applies to the other throttle bodies, can be massive; but it can also have a hollow one, so that the apparent specific weight is reduced. The throttle body must be made of a material which can withstand the pressures occurring in the borehole. The material for the throttle bodies is also expediently chosen so that it is not easily attacked by the mixture or the treatment liquid.

FIG. 5 shows a throttle body 58b which is again spherical and which is seated on a perforation 80 of the borehole casing 18. The throttle body 58 b contains a plurality of channels 86 on its surface. The channels are arranged so that a flow of mixture or treatment liquid can take place in them along the surface of the throttle body and thus also through the perforation 80 without regard to the respective orientation of the throttle body 58b with respect to the perforation on which it is seated.

The throttle body shown in FIG. 6 is also spherical. It is labeled 58c and is porous. A flow of mixture or treatment liquid takes place through the pores. This form of a throttle body is particularly useful when the pores are very fine, and it is expedient in the case of using treatment liquids which do not contain any granular material. In the case of porous throttle bodies with larger pores, these can also be used when using mixtures containing conventional material. The body 58c, too, can either be solid or have a hollow hollow, which overall results in a reduction in the weight of the throttle body and thus an apparent reduction in the specific weight.

In Fig. 7 a throttle body 58 is shown d, on de # SEN surface a network of warts 88 is provided. The height of the individual protrusions 88, measured from the level of the surface 90 , and the distribution of the protrusions 88 on the surface are selected so that a certain flow past the throttle body 58 d and through the perforation 80 is always possible. The geometrical condition for ensuring this possibility is that every circle which can be laid on the surface and which has a diameter corresponding to the diameter of the perforation 80 must pass through at least one protrusion 88.

The throttle bodies58 consist of material such as polyamides, aluminum, magnesium, bronze, steel or solid plastics or other materials which have the correct specific weight or whose apparent specific weight can be adjusted to the correct value by special geometric shaping; In addition, the materials must be able to withstand the pressures that occur. If the throttle bodies 58 are made of metal, it is expedient to start from solid grains or parcels which are sintered or fused together so that the desired porous elements 58c are obtained. Sometimes it is convenient to apply an elastic coating to the surface of the throttle body. This achieves a better fit of the throttle bodies 58 in the perforations 80 without running the risk of the throttle bodies being pushed completely into the perforations 80 and blocking them forever. It must then be ensured, however, that the elastic surface layer does not exceed a certain thickness, since otherwise the risk of the throttle bodies sticking in the bores cannot be ruled out despite the presence of the rigid core.

In the above parts of the description it was assumed that rock forinations are to be opened up by frac treatment; Of course However, the measures proposed according to the invention can also be used if any other flow may be restricted by perforations in a borehole wall target; For example, the measures proposed according to the invention can be used apply if the rock formations are to be subjected to an acid treatment.

The size of the spherical throttle bodies is important; their diameter must of course be greater than the diameter of the perforations in the well casing. If the perforations have a diameter of 9.5 mm, the throttle bodies will be given a diameter of approximately 19 mm. At this ratio, experiments have given good results. The 19 mm throttle bodies sit firmly on the 9.5 mm diameter pores, but on the other hand are large enough not to be pressed into the rock formations 16.

In the throttle bodies of the shape shown in Fig. 7 58 d the diameter of 19 mm is by two diametrically opposed warts taken 88 and is not equal to the diameter of the smooth surface 90 has. In the throttle bodies 58a of FIG. 1 , bores with a diameter of 1.6 mm have produced good results.

The ratio of the throughput through a perforation 80 with a diameter of 9.5 mm to the remaining throughput when a throttle body 58 is seated on the opening is selected as a function of various factors. One of these factors is the condition of the casing 18 and cement jacket 24; then the treatment liquid flow rate which can be maintained by the pump 36 and the pressure which is required to bring the rock formation 16 to burst comes in. The throughput through a perforation 80, against which a throttle body 58 rests, should amount to approximately 10 to 50 l, IG of the free throughput through the perforation 80 . If the throughput increases well over 50% with the throttle body 58 applied, this is not necessary in practice to avoid stresses in the borehole casing 18 and also not to prevent existing break points 82, which are connected to closed perforations 80 stand, be pushed in. For the rest, excessive flow rates with closed Porforationen are not only unnecessary, but even harmful, because they take treatment material and pump capacity in approached.

The term "throttle body" used here includes all spherical ones Bodies that, when attached to a perforation in the well casing, Reduce the throughput through this perforation considerably, but do not interrupt it completely.

A permeable throttle body, which in the method according to the invention has been used with particular success consists of crushed nutshell, which with cement or an adhesive, for example Phonol formaldehyde resin, is bound. Such a throttle body holds in the method according to the invention occurring pressures easily. In addition, the ones that come to use are Fabrics easily available.

The permeable throttle bodies, which normally have a diameter of about 22 mm, are made from crushed nutshell, preferably walnutshell; the nutshell particles are bonded to one another by an adhesive, preferably by a partially condensed liquid phenol-formaldehyde resin to which suitable catalysts have been added. An example of such a resin and the associated catalysts is described in USA. Patent 2,823,753. There you can also see the ratio of the amount of resin to the weight of the amount of nutshell used. The resins described in this patent specification have the necessary bond strength and are also insensitive to attack by the treatment liquids which occur; however, other adhesives and binders can also be used to produce the permeable throttle bodies.

Useful adhesives include plastic adhesives such as Epoxy and urea-formaldehyde resins, as well as adhesives, which are produced by solvent evaporation harden, such as B. Nitro # cellulose adhesives, and finally fabrics which by harden chemical reaction, e.g. B. Casein adhesives. The exact amounts of glue and on nutshells as well as the size of the nutshell particles for achieving one certain permeability can easily be determined by experiments.

The particle size of the nutshells expediently varies between 2.38 and 0.59 mm in diameter. Excellent results have been obtained with a particle size of between 2, 00 and 0, 84 mm in diameter and 0.84 to 0.59 mm diameter. Experiments have shown that throttle bodies made of walnut shell with a particle size within the limits given above between 176 and 211 kg per square cm of pressure difference are able to withstand without being damaged and without machining on their surface. Although throttle bodies made of larger particles, e.g. B of the order of magnitude 2.38 to 1.68 mm in diameter can be used and have a very good hardness, their surface is easily damaged if the treatment liquid contains fine solid additives which pass through the open spaces of the throttle body.

Claims (2)

PATENT CLAIMS-1. Method for treating with perforated pipe work lined boreholes by pumping fluids into those to be explored Formations with regulation of the liquid flow through the perforations by means of throttle bodies added to the liquid, characterized in that the flow through the perforations using throttle bodies which only partially close them is reduced, but not completely prevented. 2. The method according to claim 1, characterized in that by means of the throttle body, a throughput reduction is brought about at the perforations occupied by them to 90 to 50% of the free throughput. 3. Throttle body for carrying out the method according to spoke 1 undffider 2, characterized in that it has warts on its otherwise smooth surface, which prevent the throttle body from resting against the edge of the perforation. 4. throttle body for performing the method according to claim 1 and / or 2, characterized in that it is made of porous material. 5. Throttle body according to spoke 4, characterized in that it is composed of nut shell parts, preferably walnut shell parts, which are bound by an adhesive coating, deTart that the interstices causing the porosity remain free between the individual shell parts. 6. Throttle body according to spoke 5, characterized in that the nutshell parts are connected to one another by a cured phenol-formaldehyde resin. 7. DrosseJkörper according spoke 5 and / or 6, characterized in that the particle size of the nutshell parts is between 2.38 and 0.21 mm, preferably between 2.0 and 0.83 mm. 8. throttle body for performing the method according to claim 1 and / or 2, characterized in that it has open channels on its surface. 9. throttle body for performing the method according to claim 1 and / or 2, characterized in that it is penetrated by bores. 10. Throttle body according to claim 9, characterized in that it is formed by a hollow spherical shell, the wall of which is penetrated by radially extending bores. 11. Throttle body according to emern of claims 3 to 10, characterized in that it is composed of an outer shell of higher specific weight and an inner none of lower specific weight. References considered: U.S. Patent No. 2,754,910.