NO172131B - USE OF SELECTED ETHERS IN MINERAL OIL-FREE WATER-IN-OIL EMULSION DRILLS - Google Patents

Description

The present invention relates to the use of selected ethers in mineral-free water-in-oil emulsion drilling mud.

More specifically, the invention relates to the use of certain water-insoluble ethers of monohydric alcohols of natural and/or synthetic origin, as oil phase or components of the oil phase in water-in-oil emulsion drilling mud.

With the help of the present invention, the new drilling mud, as described in NO application 911706, is obtained, which is distinguished by high ecological tolerability with at the same time good storage and use properties. An important area of application for these drilling muds is offshore drilling for the extraction of oil and/or natural gas deposits, whereby the invention here particularly aims to provide technically usable drilling muds with a high ecological tolerance. The application of the new drilling mud systems has particular importance in the maritime area, but is not limited to this. The new drilling mud systems are also generally used in land-based drilling, for example in geothermal drilling, water drilling, geoscientific drilling or drilling in ordinary rock works. In general, however, it also applies here that by using the selected ethers of the invention, the ecotoxic problem area is simplified to a significant extent.

Oil-based drilling mud is generally used as so-called invert emulsion mud, which consists of a three-phase system: oil, water and finely divided solids. This concerns preparations of the water-in-oil emulsion type, that is to say that the aqueous phase is distributed heterogeneously and finely dispersed in the continuous oil phase. In the following, these water-in-oil emulsions are also called "invert emulsions". For stabilization of the overall system and for setting the desired usage properties, a number of additives are aimed at, especially emulsifiers or emulsifier systems, weighting agents, liquid-loss additives, alkali reserves, viscosity regulators and the like. When it comes to details, for example, reference can be made to a publication by P.Å. Boyd et al., "New Base Oil Used in Low-Toxicity Oil Muds", "Journal of Petroleum Technology", 1985, 137-142 as well as by R.B. Bennett, "New Drilling Fluid Technology - Mineral Oil Mud", "Journal of Petroleum Technology", 1984, 975-981, and references therein.

The available technology has for some time recognized the importance of ester-based oil phases in order to reduce the problems arising from such oil sludge. Thus, US-PS 4,374,737 and 4,481,121 describe oil-based drilling muds in which non-polluting oils are used. Non-polluting oils are mentioned next to each other and as equivalent, aroma-free mineral oil fractions and vegetable oils of the type peanut oil, soybean oil, linseed oil, corn oil, rice oil, or also oils of animal origin such as whale oil. All the time, the ester oils of vegetable and animal origin mentioned here are triglycerides of natural fatty acids which, as is known, have a high environmental tolerance and which have a clear superiority over hydrocarbon fractions, also when these are aroma-free, in terms of ecological considerations.

It is quite interesting, however, that no example is given in the mentioned US patents of the use of such natural ester oils in invert drilling mud of the type described here. All the time, mineral oil fractions are used as closed oil phase. Oils of vegetable and/or animal origin are not considered for practical reasons. The rheological properties of such oil phases are difficult to control for the practically required temperature ranges of 0 to 5°C on the one hand and up to 250°C and above on the other hand.

Ester oils of the type described here also do not behave like the mineral oil fractions currently used on a pure hydrocarbon basis. In practical use, ester oils also undergo partial hydrolysis precisely in invert drilling mud. This creates free carboxylic acids. NO applications 912337 and 912338 describe the resulting problems and provide proposals for their solution. Further varieties of usable ester oils are described in NO applications 913239 and 913240.

The subject of these older applications is the use of ester oils based on each time selected monocarboxylic acids, respectively monocarboxylic acid mixtures and monofunctional and possibly multifunctional alcohols. Be older applications describe that with the esters or ester mixtures described there, not only can satisfactory rheological properties be set in the new drilling muds, but that it is also possible to work with the combined use of selected known alkali reserves in the drilling muds and in this way to slow down unwanted corrosion. As an alkali reserve, one aims, especially when using ester oils based on carboxylic acids with at least 6 C atoms, the addition of lime (calcium hydroxide or "lime") and/or the combined use of zinc oxide or comparable zinc compounds. Thereby, however, a further restriction is appropriate. If, during practical operation, unwanted thickening of the oil-based invert drilling mud is to be prevented, the amount of alkalizing additives and especially the amount of lime must be limited. The intended maximum amount is, according to what is described in the older applications, approximately 2 lb/bbl oil spray liquid.

(conversion factor: 1 lb/bbl = 2.8530 g/l).

An important further development of such ester oil-based invert drilling mud is the subject of NO application 913041.

The teaching in these older applications is based on the concept, in invert drilling mud based on ester oils, in addition to using an additive that is suitable to keep the rheological data in the drilling mud within the intended range even when in use, larger amounts of free carboxylic acid by partial ester hydrolysis. These free carboxylic acids must not only be captured in a harmless form, but it must also be possible, if desired, to convert the free carboxylic acids into valuable components with stabilizing or emulsifying properties for the overall system. According to this teaching, the aim is to co-use basic amine compounds usable for salt formation with carboxylic acids, with a pronounced oleophilic nature and very limited water solubility as an additive in the oil phase. The oleophilic amine compounds can at least partially find use as an alkali reserve in the invert drilling mud, but they can also be used in combination with conventional alkali reserves and especially together with lime. The use of oleophilic amine compounds which are at least predominantly free of aromatic components is preferred. In particular, optionally olefinically unsaturated, aliphatic, cycloaliphatic and/or heterocyclic, oleophilic, basic amine compounds which contain one or more N groupings which can form salts with carboxylic acids come into consideration. The water solubility at room temperature for these amine compounds constitutes a preferred embodiment of no more than 5% by weight and is suitably below 1% by weight.

Typical examples of such amine compounds are, at least to an extensive extent, water-soluble, primary, secondary and/or tertiary amines, which may also be to a limited extent alkylated and/or substituted with hydroxyl groups in particular. Further examples are corresponding amino amides and/or heterocycles containing nitrogen as a ring component. Suitable are, for example, basic amine compounds which at least have a long-chain hydrocarbon residue with preferably 8-36 C atoms, especially with 10-24 C atoms which can also be one or more times olefinically unsaturated. The oleophilic basic amine compounds can be added to drilling fluids in amounts of approx. 10 lb/bbl, preferably in quantities of approx. 5 lb/bbl and especially in quantities within the range of 0.1-2 lb/bbl.

It has been shown that the co-use of such oleophilic basic amine compounds can effectively prevent thickening of the flushing system, which is presumably due to a disturbance of the water-in-oil invert system and which can be traced back to the formation of free carboxylic acids by ester hydrolysis .

The present invention is based on the task of further developing systems of the type in question and in particular drilling mud with a high ecological tolerability. In a first embodiment, the invention will make available oils or oil mixtures for building up drilling mud on the basis of water-in-oil emulsions which are technically usable and easily available and which at the same time are distinguished by a high ecological value. In a further embodiment, the invention will provide additives for the above-described systems of the type in question here which give drilling mud on a water-in-oil emulsion basis valuable additional properties without the ecological tolerability being unfavorably affected.

The technical solution to the invention's task is based on the recognition that ethers selected and adapted to the area of application in question can be transferred to new and improved drilling mud of the specified type. These ethers refer to water-insoluble or essentially water-insoluble components, in particular corresponding compounds with a pronounced oleophilic character which, however, differ from the pure hydrocarbon compounds by the presence of functional ether groups. In this way, important technological improvements become available while ensuring a high ecological tolerability.

According to this, the present invention relates to the use of water-insoluble ethers of monohydric alcohols of natural and/or synthetic origin with 4-36 C atoms, preferably 6-24 C atoms in the alcohol residue, with a flash point above 80°C, as an oil phase or component of the oil phase of water-in-oil emulsion drilling mud, and which, if desired, exhibits further known additives.

According to the present invention, the water-in-oil emulsion drilling mud is used which is suitable for an environmentally friendly utilization of oil and natural gas deposits and which in a continuous oil phase contains a dispersed aqueous phase together with usual, additional auxiliary substances, for example emulsifiers, weighting agents, liquid loss additives and alkali reserves, where these sludges as a continuous oil phase or dissolved in ecologically acceptable, water-insoluble oils contain an addition of the substantially water-insoluble ethers of monohydric alcohols, whereby the relevant oil phase in the temperature range of 0 to 5°C is flowable and pumpable and exhibits flash points above 80"C.

In a first embodiment, the continuous oil phase in the invert drilling mud is formed exclusively or to a predominantly extent, so to speak, of the essentially water-insoluble or preferably distinctly oleophilic ethers. Of course, here the rheology of the ether used must be adapted to the technical requirements for the drilling mud. Light rheological corrections are possible by co-using the intended small amounts of diluents in this embodiment. In the case described here, oil phases which are formed from more than 70 wt.#, preferably more than 80 wt.# and preferably so to speak excluded by the ethers as such, come into consideration. The rheological requirements for such oils are subject to general technical knowledge in the field of application of the drilling mud, and this will be discussed in more detail below.

Within the scope of the invention's definition of the term suitable ether, ethers that are generally symmetrical and each time traceable to a selected alcohol, mixed ethers of different alcohols and/or ether mixtures of the two above-mentioned ether types fall. From the wide range of suitable individual ethers or mixed ethers and/or ether mixtures, in particular the corresponding representatives come into consideration which are at least partially corresponding derivatives of monofunctional alcohols with at least 6 or 7 C atoms, preferably with at least 8 C atoms, whereby the possible upper limit of the carbon number is strongly influenced by the structure of the hydrocarbon residue. The known influence of the branched and/or unsaturated structure of the hydrocarbon residue in the corresponding alcohols affects the rheology of the ether obtained therefrom.

As is known, the rheology of branched and/or unsaturated ethers of the type described here fulfills the requirements for flowability and pumpability, even at low temperatures, more easily than the straight-chain, saturated hydrocarbon skeleton. Saturated, straight-chain fatty alcohol ethers from the area Cit— 18 nar known high solidification areas. Branched ethers from the same carbon number range can, depending on the degree and extent of the branching, certainly be usable liquid and pumpable oil phases within the context of the invention. In the area of saturated ethers of monofunctional alcohols, however, especially the area with a lower carbon number is suitable, especially the area approximately Cg_i4, whereby here also the ethers of branched alcohols can have rheological advantages.

In this embodiment, the oil mixture components that can be used to a small extent can be pure, especially aromatic-free hydrocarbon compounds, especially, however, selected ester oils of the type mentioned in the previous applications.

The inherent rheology of the ether components used according to the invention becomes increasingly less important the greater the proportion of this mixture component in the mixture with one or more oil components. Oil phases are used in systems in systems of the type in question which, however, already exhibit significant or even predominant amounts of water-immiscible oils which can be used in admixture with the ethers included in the invention. The content of selected ethers in the invention in these embodiments is usually above 10% by weight and up to 70% by weight, calculated on the liquid oil phase, whereby the ether portion is preferably in amounts of at least 35% by weight and most preferably less than 50% by weight # of the oil phase.

As a mixture component for this second embodiment, both pure and especially aromatic-free hydrocarbons, as well as above all ester oils of the type described in the above-mentioned older applications, come into consideration. Mixtures of these types also fall within the scope of the invention whereby both mixtures of ester oils with pure hydrocarbon compounds and mixtures of different ester oil types can be mixture components for the joint use with the oleophilic ethers. In preferred embodiments of the invention, pure hydrocarbons which do not exhibit any functional groups are used in amounts of at most 50 wt-#, preferably at most 35 wt-$ and most preferably at most 25 wt-#, calculated on the weight of the oil phase. In the most important embodiments of the variant described here, mixtures of the invention's defined ethers and ester oils are used as the oil phase without the addition of pure hydrocarbons.

The practically water-insoluble ethers are co-used as an additive in the oil phase of the above-described drilling mud on the basis of water-in-oil emulsions. The quantity of the ethers of the invention used here is usually in the range of 0.1 to a maximum of 10% by weight, preferably in the range of 1 to 5% by weight of the oil phase. The range of suitable water-insoluble ethers can, as will be understood, be significantly expanded in this embodiment. The rheology of the total system is no longer determined by the ether's rheological values. Precisely in this embodiment of the use of the ethers used in the invention as an additive, however, important improvements are achieved in the behavior of drilling mud of the type described above.

In particular, this applies to invert systems where the main component of the continuous oil phase is exclusively or predominantly formed by ester oils of the type mentioned in the above-mentioned applications. In the embodiments described here, the main components for the oil phase according to this are present at least in an amount of at least 25 wt-#, preferably at least 50 wt-# and most preferably 75 to 80 wt-# of the oil phase, as ester oil. As a residue, you can use pure hydrocarbons from the known technique, but preferably you completely forgo such.

By adding the water-insoluble ether used according to the invention to the invert systems, important improvements for the practical use of the drilling muds can be achieved. In particular, this applies to the following four sub-aspects: reduction of the liquid-loss value, facilitation and improvement of emulsification of the dispersed aqueous phase, a possibly clearly improved lubrication effect of the drilling mud and possibly a clear improvement of the rheological properties of the ester oil-based invert drilling mud.

The use of the ether as an oil phase, but also its co-use as a quantitatively subordinate or superior proportion in the oil phase, requires sufficient water insolubility for the ether. Preferably, the water solubility of suitable ethers at room temperature is below 5 wt-#, especially below 1 wt-# and most preferably at no more than 0.1 wt-#.

As far as the chemical nature is concerned, the following general rules apply: The particular structure of the ethers used within the framework of the invention is determined above all by the chosen embodiment in question in which the composition of the ether-containing oil phase is chosen, reference should be made to the above.

If the ether forms the oil phase alone or the ether is present at least as a predominant mixture component in the mixture used which constitutes the continuous oil phase, the choice of the suitable ether or ether mixture is first determined by the corresponding main rheological data. In simplicity, it applies here that the ether or the other ether mixture in the temperature range from 0 to 5°C exhibits a Brookfield-RVT viscosity that is not more than 50 mPas, preferably not more than 50 mPas, and especially not more than 30 mPas. At the same time, the solidification value (pour and solidification point) of the ether in question should be below 0°C. Preferably, ethers or ether mixtures with solidification values below -5°C and especially below -ICC are used.

Finally, for the practical application, the flash point of the ether used is also important, it should preferably not be below 90°C and most preferably above 100°C. Significantly higher flash points, for example those above 130°C and especially above 150°C, may be particularly appropriate.

As already discussed above, the totality of the rheological properties and the flash point are strongly influenced by the individual molecular structure of the ether-forming alcohols. In addition to these structural features, the following can be said.

An important element of the invention is the use of comparatively non-toxic components so that, for example, the use of aromatic ethers, especially of the phenol ether type, is practically excluded. Aliphatic, possibly mono- and/or multiple olefinically unsaturated alcohols with a straight and/or branched structure and possibly cycloaliphatic alcohols are the most important ether-forming components within the context of the invention. The lower limit for the number of hydrocarbons in such alcohols is at C4, preferably at C2, and most preferably at Cg. Depending on rheological requirements, the upper limit for the number of carbons in the ether-forming alcohols can also be chosen very high and is, for example, approx. C36, preferably at approx. C32. Special monofunctional alcohols in the range C6_24' preferably C6-18' Ethers from c8_16- °S especially cg_14_ alcohols are suitable components within the teachings of the invention.

The ether-forming alcohols can thereby, or at least partially, be straight and/or branched, even and/or odd, saturated and/or unsaturated. The ether-forming alcohols can thereby also be wholly or partly of natural and/or synthetic origin.

Suitable are, within the framework of the specified boundary conditions, specific selected ethers or ethers of specific selected alcohols, mixed ethers of specific selected alcohols and/or ether mixtures. As the ether function is inert both to the constituents introduced via the drilling fluid and to the chemical effects occurring in connection with the actual passage of the drilling fluid, at least to a significant extent, this also applies in particular precisely to the basic water-in-oil invert emulsion -basis, there is practically freedom of choice here so that the rheological data required for the drilling fluid can be optimally set and fulfilled. The secondary reaction during operation, as they are typical for the ester oils in basic water-in-oil invert emulsions, is not at all heavy for the ether as an oil phase or as a mixture component in the oil phase.

For mixing within the scope of suitable oil components used in the invention, the ones used in current practice are mineral oil and thereby preferably essentially aromatic-free aliphatic and/or cycloaliphatic hydrocarbon fractions with the necessary flow properties. Reference is made to today's known technology and the commercial products available on the market.

Particularly important mixture components are, however, within the framework of the invention, environmentally compatible ester oils as they are particularly described in NO application 912337, 912338, 913239 and 913240. To complete the description, essential characteristic data for such esters and ester mixtures are given below.

In a first embodiment, in the temperature range 0 to 5°C, flowable and pumpable esters of monofunctional alcohols with 2-12 and especially 6-12 C atoms, and aliphatic saturated monocarboxylic acids with 12-16 C atoms and their mixtures with at most approximately the same amounts of other monocarboxylic acids as the oil phase. Preference is therefore given to ester oils which in an amount of approx. 60$, calculated for the carboxylic acid mixture in question, are esters of aliphatic <C>12_14-monocarboxylic acids and where possibly the rest is to lead back to subordinate amounts of shorter-chained aliphatic and/or longer-chained, then especially one- or several-fold olefinically, unsaturated monocarboxylic acids. Preferably, esters are used which in the temperature range between 0 and 5°C exhibit a Brookfield-RVT viscosity in the range not exceeding 50 mPas, preferably not exceeding 40 mPas, and especially not more than 30 mPas. The esters used in drilling mud exhibit solidification values (flow and solidification points) of below -10°C, preferably below -15°C, and thereby particularly have flash points above 100°C and preferably above 150°C. The carboxylic acids present in the ester or the ester mixture are straight-chain and/or branched and thus of vegetable and/or synthetic origin. They can be derived from corresponding triglycerides such as coconut oil, palm kernel oil and/or babassu oil. The alcohol residues in the esters used are derived in particular from straight-chain and/or branched, saturated alcohols with preferably 6-10 carbon atoms These alcohol components can also be of vegetable and/or animal origin and can thereby be obtained by reductive hydration of corresponding carboxylic acid esters.

A further class of particularly suitable ester oils are derived from mono- or polyunsaturated carboxylic acids with 16-24 C atoms and their mixtures with smaller amounts of other, especially saturated monocarboxylic acids and monofunctional alcohols with preferably 6-12 C atoms. These ester oils are also flowable and pumpable in the temperature range 0 to 5°C. Particularly suitable are esters of this type which, in an amount of more than 70 wt-£, preferably more than 80 wt-# and especially more than 90 wt-#, are derived from olefinically unsaturated carboxylic acids in the range ^^£)_24'

Here, too, the solidification values (flow and solidification points) are below -10°C and preferably below -15°C, while the flash points are above 100°C and preferably above 160°C. The esters used in drilling mud exhibit in the temperature range from 0 to 5°C a Brookfield-RVT viscosity of no more than 55 mPas, preferably no more than 45 mPas.

For ester oils of the type in question here, two subclasses can be defined. In the first, the unsaturated C^_2£<->monocarboxylic acid residues present in esters are derived in an amount of no more than 35% by weight from doubly or more olefinically unsaturated acids, whereby preferably at least 60% by weight of the acid residues are once olefinically unsaturated. In the second embodiment, the <C>16-24-monocarboxylic acids present in the ester mixture are derived in an amount of more than 45% by weight, preferably more than 55% by weight, from doubly or more olefinically unsaturated acids. In the ester mixture present saturated carboxylic acids from the range ci£_ig suitably amount to no more than 20 wt-56 and preferably no more than 10 wt-#. Preferably, however, saturated carboxylic acid esters lie in the range of lower carbon numbers for the acid residues. The present carboxylic acid residues can be of vegetable and/or animal origin. Vegetable starting materials are, for example, palm oil, peanut oil, castor oil and especially beet oil. Carboxylic acids of animal origin are particularly similar to mixtures of fish oils such as herring oil.

A further interesting class of ester oils which can be used as a mixture component within the scope of the invention are at room temperature flowable esters with a flash point above 80°C, of C2-g-monocarboxylic acids and mono- and/or polyfunctional alcohols which, however, are preferably also flowable and pumpable in the temperature range 0 to 5°C. Particularly suitable are corresponding esters of these lower carboxylic acids with monofunctional alcohols with at least 8 C atoms and/or esters of these acids with di- to tetrahydric alcohols with preferably 2-6 carbon atoms. As ester-forming acid components of this type, acetic acid in particular is suitable for practical reasons. Measured figures for rheology and volatility respectively the solidification values for preferred esters in this subclass correspond to the values mentioned above.

Suitable as a mixture component from this subclass are especially esters of monofunctional alcohols of natural and/or synthetic origin whose chain length reaches

predominantly aliphatically saturated alcohols are present, lie in the range cg_15t in the case of mono- and poly-olefinically unsaturated alcohols, however, can also lie at higher C-numbers, for example at approx. C24. Details can be found in NO application 913239.

Finally, however, suitable mixture components are the esters of monocarboxylic acids of synthetic and/or natural origin described in NO application 913240 with 6-11 C atoms and mono- and/or polyfunctional alcohols which are preferably also flowable and pumpable in the temperature range from 0 to 5°C. In order to complete the description of the invention, reference is thus made to the aforementioned NO patent documents.

oil phase or at least as a component of a closed oil phase of such water-in-oil invert emulsions in NO application 913042. To the extent that they affect the present invention, reference is made there.

The scope also includes multi-substance mixtures which, together with the ethers defined according to the invention, may contain one or more of the mixture components listed here individually. Thereby, in principle, any mixtures can be used as long as they meet the main rheological requirements for invert drilling mud of the type described here. As examples of such multi-component mixtures, materials based on different types of ester oils or additionally mixtures containing mineral oil should be mentioned.

As additional mixture components in the invert drilling fluid, all common mixture components for conditioning and for practical use of the invert drilling muds, as they are used according to current practice with mineral oil as continuous oil phase, come into consideration. Next to the disperse phase, emulsifiers, weighting agents, liquid loss additives, viscosity formers and alkali reserves are particularly taken into account here.

In an important embodiment, oleophilic basic amine compounds are used as additives together with the ester oils as they are described in detail in the initially mentioned NO application 913041. For the sake of simplicity, reference is made to this for details.

If, within the framework of the invention, ester oils are used as mixture components, particularly ester oils based on carboxylic acids with at least 6 C atoms, it may be appropriate not to use significant amounts of strongly hydrophilic inorganic and/or organic bases in the drilling mud. Lime can be used effectively as an alkali reserve. In this case, however, it is appropriate to limit strongly hydrophilic bases of an inorganic and/or organic nature. Lime can be used effectively as an alkali reserve. In this case, however, it is appropriate to limit the maximum amount of lime used to approx. 2 lb/bbl, whereby it may be preferred to work with drilling mud fillings of lime that are slightly below that, for example in the range of 1 to 1.8 lb/bbl (lime/drilling fluid). Next to or instead of the lime, other alkali reserves of a known type can be used. Particular mention should be made here of the less basic metal oxides of the zinc oxide type. However, also when using such acid scavengers, care must be taken not to use excessive amounts in order to prevent an undesired premature change of the drilling mud, associated with an increase in viscosity and thereby deterioration of the rheological properties. Due to the specialty of the invention discussed here, unwanted amounts of highly effective oil-in-water emulsifiers are prevented or at least significantly reduced, so that the good rheological values can also be maintained by the thermal change in operation for a sufficiently long time time.

Furthermore, the following applies:

Invert drilling muds of the type described herein usually contain, along with the continuous oil phase, the finely dispersed aqueous phase in amounts of 5 to 45 wt-5 and preferably in amounts of 5 to 25 wt-#. The range of 10 to 25 wt-# dispersed phase has a slightly special significance.

For the rheology of preferred invert drilling muds the following rheological data apply: plastic viscosity (PV) in the range 10-60 mPas, preferably 15-40 mPas, yield point (Yield Point YP) in the range 5-40 lb/100 ft2 , preferably 10-25 lb/100 ft2, all determined at 50"C. (Conversion factor: 1 lb/100 ft<2> = 2.0885 Pa). For the determination of this parameter, for the measurement method used thereby and for the other usual composition of the invert drilling muds described here apply to what is indicated in the known technique indicated at the beginning as well as "Oil Mud Technology". As a conclusion, to complete the description of the invention, the following can be said: Practically usable emulsifiers are systems that are suitable for formation of the required water-in-oil emulsion. Specially selected oleophilic fatty acid salts, for example those based on amidoamine compounds, are taken into consideration. Examples of such are described in the already mentioned US-PS 4,374,737 and the literature cited there. A particularly suitable emulsifier type is that commercially available from the company NL Baroid under the trade name "EZ-mul".

Emulsifiers of the type described here are commercially available as highly concentrated active ingredient preparations and can find applications in quantities of 2.5-5 wt-#, especially in quantities of 3-4 wt-#, always intended for the oil phase.

As a liquid loss additive and thus especially for the formation of a dense coating on the borehole walls with a largely liquid impermeable film, particularly hydrophobic lignite is used in practice. Suitable amounts are, for example, within the range of 15-20 lb/bbl or in the range of 5-7 wt-#, calculated for the oil phase.

In drilling mud of the type described here, the commonly used viscosity former is a cationic, modified finely divided bentonite which can be used especially in quantities of 8-10 lb/bbl or in the range of 2-4 wt-#, calculated on the oil phase. In normal practice, the weighting agent usually used to set the necessary pressure equalization is baryte, the amount of which must be added to the intended conditions during drilling. It is, for example, possible to increase the specific gravity of the drilling mud to values in the range up to 2.5 and preferably to values in the range 1.3-1.6, by adding baryte.

In invert drilling mud of the type in question here, the disperse phase is filled with soluble salts. Predominantly calcium chloride and/or potassium chloride are used here, whereby saturation of the aqueous phase at room temperature with the soluble salt is preferred.

The above-mentioned emulsifiers or emulsifier systems also serve to improve the oil crosslinking ability of the inorganic bulking materials. Alongside the already mentioned amino amides, alkyl benzosulfonates and imidazoline compounds should also be mentioned as further examples. Further information with regard to the known technique can be found in GB 2 158 437, EP 229 912 and DE 32 47 123.

The invention shall be further illustrated with reference to the following examples (where 1 lb/100 ft<2> = 2.0885 Pa):

Example 1

An invert mud is prepared with an oil:water ratio of 90:10 according to the following recipe:

239 ml of dialkyl ether n-C8

6 g of gel form (commercial product ("Omnigel")

9 g water-in-oil emulsifier ("EZ-mul NT" from Fa. NL Baroid) 20 g organophilic lignite ("Duratone" from Fa. NL Baroid)

28 g of water

12 g of CaCl2 x 2H2O

4 g of lime

255 g baryte

On the invert drilling mud, the plastic viscosity, PV, the yield point, YP, and the gel strength after 10 seconds and after 10 minutes are first determined by viscosity measurement at 50°C on the non-aged material.

The invert drilling mud is then aged for 16 hours at 125°C in an autoclave in a so-called "Roller oven" to determine the influence of temperature on emulsion stability. Then the water temperature value at 50°C is determined again.

The established values of non-aged and aged material are as follows:

HTHP liquid loss value after aging equal to 4 ml.

Example 2

An invert drilling mud is produced with an oil/water ratio of 80:20 according to the following recipe:

210 ml of dialkyl ether according to example 1

6 g of gel form (commercial product ("Omnigel")

13 g of organophilic lignite ("Duratone" from Fa. NL

baroid)

48.2 g of water

20 g of CaCl2 x 2H2O

8 g water-in-oil emulsifier ("EZ-mul NT" from Fa. NL

baroid)

2 g lime

250 g baryte

The established values of non-aged and aged material are as follows:

HTHP liquid loss value after aging equal to 1 ml.

Examples 3-5

In the following examples, invert drilling mud is prepared with an oil:water ratio of 90:10 according to the following recipe: 230 ml of ether (see the subsequent identification in examples 3-5)

26 ml of water

6 g gel form (commercial product ("Geitone")

12 g organophilic lignite ("Duratone" from Fa. NL Baroid)

2 g lime

6 g water-in-oil emulsifier ("EZ-mul NT" from Fa. NL Baroid)

346 g baryte

9.2 g of CaCl2 x 2H2O

Individually, the following ethers are used as oil phase:

Example 3: Cg-O-C8

Example 4: Ciq-0-Ciq

Example 5: di-isotridecyl ether

The viscosity values measured on unaged and aged drilling fluids are summarized below. Thereby, aging is determined once after 16 hours at 125°C and in a further test after 72 hours at 125°C.

Example 3

Example 4

The trial rates for this example are obtained in the following way: For the aging over a period of 72 hours, a drilling mud with the specified recipe is used, to which 2 g of distinctly oleophilic amine (commercial product "Araphen G2D" from the applicant's company) has also been added. The following values are determined:

Example 5

Claims (1)

Use of water-insoluble ethers of monohydric alcohols of natural and/or synthetic origin with 4-36 C atoms, preferably 6-24 C atoms in the alcohol residue, with a flash point above 80°C, as oil phase or component of the oil phase in mineral oil-free water in-oil emulsion drilling mud, and which, if desired, exhibits additional, known additives.