DE1198762B - Method for cleaning a borehole - Google Patents

Description

Method of cleaning a borehole The invention relates to on the cleaning of boreholes to remove deposits of paraffin and others to remove highly viscous hydrocarbons.

The extraction of petroleum or gas from an underground formation Difficulties are often encountered through a borehole leading to the surface of the earth due to the accumulation of heavy hydrocarbons within the borehole. Heavy hydrocarbons accumulate due to lowering of temperature and other factors, like paraffin and tar, inside the borehole, which leads to blockages. Buildings occur, for example, at the perforations of the liner and the pipes, inside the riser pipes and also in pumps, on sucker rods and in other places on. These accumulations are solid or under the conditions prevailing in the borehole semi-solid and narrow the passageways in the borehole, reducing the flow of fluid or gas is restricted. In unfavorable cases, the media flow through the Borehole can be completely prevented.

Attempts have been made to treat such accumulations with a solvent for heavy hydrocarbons to dissolve them out wash out and remove the borehole. However, these measures are common unsuccessful. Apparently the accumulations form a mass of heavy hydrocarbons, which are emulsified with the water produced together with the petroleum or gas. The emulsified water hinders and delays the action of the solvents the mass and dissolution of the heavy hydrocarbons in an efficient manner. In addition, the accumulations on their outer surfaces are evidently with a covered by a thin film of water, which further impairs the effectiveness of the solvents.

The invention will reduce the accumulation of heavy hydrocarbons based difficulties eliminated.

The method according to the invention for cleaning a borehole, which contains an accumulation of heavy hydrocarbons is characterized by that in a two-step procedure, the accumulation is initially known per se Way with a liquid mixture that is a solvent for the hydrocarbons and a surfactant, treated and thereafter in contact with water brings.

It is preferably used in a manner known per se with a surface-active Substance mixed water applied. Both the solvent as well as subsequently the water moves while it is in contact with the hydrocarbon accumulation are located.

It is known in the extraction, forwarding and storage of Petroleum or natural gas in the oil respectively. Gas probes themselves or in those for extraction, forwarding and storage facilities such as pipelines, pumps and tanks Bringing halogen-containing wax-dissolving agent in order to avoid disturbances caused by wax deposition to prevent or remedy. The well-known method of operation comprises only one stage, namely the treatment of the wax deposit with a mixture of a halogenated olefinic compound and a halogenated aromatic compound, the Mixture may optionally contain a non-ionic wetting agent. A subsequent Work stage corresponding to the second combination stage of the method according to Invention in which the accumulation of heavy hydrocarbons with water in Is brought into contact, especially with accompanying movement, comes with the known processes are not considered. The known method is therefore not suitable to solve the problem underlying the invention satisfactorily.

It is also known to have a pipeline with an inner coating which consists of various water-insoluble materials. These Substances bring the pipeline into a water-wetted state. The coating compound is applied to a clean surface of the pipeline. Also here acts it is a one-step procedure and there is no information on how one Accumulation of heavy hydrocarbons from a borehole or pipeline could be removed. This known method could therefore not lead to a Solution of the problem on which the invention is based contribute.

According to the invention it has been determined that the hydrocarbon buildup by contacting in a borehole with a liquid mixture containing a Comprises solvents for hydrocarbons and a surfactant, to be softened. The mixture of the solvent and he interacting with it Surfactant is capable of forming a film of water from the outer surface to displace the accumulation and the mass of heavy hydrocarbons emulsified with water to penetrate. Due to the presence of the emulsified water, however, this leads Penetration does not result in a dissolution of the hydrocarbons, but only in one Preconditioning of the accumulation for the action of the water. In the following Treatment with the water in the second stage of the procedure will be the most severe Hydrocarbons dispersed in the water. This removes the accumulation their position in the borehole, and their obstruction of the flow of media through the Passages in the borehole are thus eliminated. With subsequent flow of water out of the borehole accompany the dispersed heavy hydrocarbons the water and are removed from the borehole.

There can be several types of hydrocarbon solvents in the first stage of the process, e.g. B. liquid unsubstituted halogenated, amine substituted, or oxygenated hydrocarbons including Alcohols, ketones and acids. These can be aliphatic or aromatic in nature be. These include petroleum fractions such as kerosene or kerosene-like fractions, z. B. purified kerosene fractions, gasoline, benzene, xylene. Toluene, n-pentane, n-heptane, Chlorhexylamine, propylenediamine, ethylenediamine, diethylenetriamine, methylene chloride, Perchlorethylene, carbon tetrachloride, chloroethane, dioxane, methyl ethyl ketone, acetic acid, Carbon disulfide and the cresylic acids. Toluene, xylene or benzene are preferred used. Mixtures of two or more solvents can also be used will. Optionally, a corrosion inhibitor can be added to the solvent will.

As the surface active substance in the first; Any compound having surface-active properties and solubility in both oil and water can be used at the stage of the process. Such substances have a water-soluble and an oil-soluble part and can to some extent dissolve in both water and oil . Depending on the hydrophilic properties of the water-soluble part and the lyophilic properties of the oil-soluble part, the compound may be more soluble in water than in oil or more in oil than in water. Surface-active substances which have a greater degree of solubility in water than solubility and those which are non-ionic are preferred. An oxyethylene ether of an alkylaryl compound is preferably used, the alkylaryl part, ie the lyophilic part, having 9 to 18 carbon atoms and the oxyethylene part, ie the hydrophilic part, between 20 and 50 mol of ethylene oxide. Particularly good results have been obtained when using the oxyethylene ethers of nonylphenol, in which the oxyethylene chain contains an average of 30 moles of ethylene oxide.

The surfactant should be in the liquid mixture be included in an amount of at least 0.1 percent by weight; preferably be however, larger amounts are used. For example, 5 percent by weight became more surface-active Substance, based on .the mixture, achieves satisfactory results, it can but also 10 percent by weight, based on the mixture, can be used.

The amount of liquid mixture from the solvent to use for hydrocarbons and the surfactant depends on the one to be displaced Amount of hydrocarbon build-up. Usually the latter is difficult to determine. However, if it is known, the amount of liquid mixture should be at least the same be half the volume of the collection. Larger amounts can be used, for example, the same volume as that of the cluster. To get adequate treatment of the borehole, the volume of liquid mixture should match the volume the passageways within the borehole, the accumulations to be removed are harder Contains hydrocarbons, be the same. Treatment with the liquid mix can be repeated one or more times if necessary.

In the second stage of the process, the hydrocarbon build-up occurs brought into contact with water within the borehole. This causes emulsification the heavy hydrocarbons with the water causes. The process is through movement of the water. This movement can be caused by the flow of water at the place of the Hydrocarbon accumulation or where an otherwise calm water phase comes into contact located with the accumulation, by passing a gas through the water phase to Induction of a foaming, bubble or effervescent effect or by other means can be achieved.

The amount of water used in the second stage of the process can be with the amount of liquid mixture used in the first stage of the process from the solvent for hydrocarbons and the surfactant to match. However, larger volumes of water are preferably used, for example 3 to 5 times this volume or possibly even larger volumes, e.g. B. 10 or more times this volume.

Preferably contains that used in the second stage of the process Water is also a surface-active substance because it is faster and more effective Displacement and emulsification of the heavy hydrocarbons occurs. In a mixture with the water can have the same surfactants as in the mixture to be used with the solvent for hydrocarbons. Preferably will an oxyethylene ether of nonylphenol, in which the oxyethylene chain on average 30th Contains mol of ethylene oxide, used. The amount of surfactant should be at least 0.1 percent by weight, based on the amount of water. It can larger amounts, for example 5 to 10 percent by weight of the mixture, are used will.

If desired, the accumulation can be treated with water once or repeated several times, as well as treating the accumulation with the liquid Mix in the first stage. Therefore, the treatment with water can follow each treatment with the liquid mixture can be carried out one or more times, or it can be postponed regardless of whether it is performed one or more times be carried out until the treatment with the liquid mixture two or more times has been. If desired, the working stages of the treatment with the liquid Mixture of hydrocarbon solvent and surfactant and alternate with water.

Following the treatments with the liquid mixture and with the water removes the emulsified accumulations from their position in the borehole, for example by a flow of liquid or gas from the producing earth formation to the borehole or by introducing a medium into the borehole. For example a gas can be injected into the borehole to form a foam and this to remove from the borehole. Other methods of removing the the water from the wellbore containing the emulsified hydrocarbon pool be applied.

From a producing earth formation occurs together with the gas or Often times oil into the wellbore. In these cases, part or all of the amount can be used of the water for the second stage of the process can be obtained by adding water can flow from the earth formation into the borehole. If in the second stage water to be used in a mixture with a surface-active substance, the surface-active substance, optionally mixed with a liquid, in introduced the borehole and mixed with the produced water. Should be expedient however, water can be introduced into the borehole without regard to production of water from the earth formation.

In many cases, buildup becomes heavier after removal Hydrocarbons the conditions that cause such accumulations to form, persist so that accumulations can occur again. It was found, that this is done by periodically treating the borehole with a mixture a solvent for hydrocarbons and a surfactant can be prevented. The substances described above can be used for this will. The mixture of the solvent for hydrocarbons and the surface active Substance is introduced into the borehole and passed through the passageways, where an accumulation of heavy hydrocarbons would occur, such as on the ground of the borehole through the pipes so that they are together with the medium produced flows through the borehole. This treatment can be done at daily intervals or less done frequently. Apparently the mixture keeps a water-moist surface of the passageways, through which the medium flows, upright. These water-damp surfaces do not leave any Deposition of heavy hydrocarbons too, and the formation of agglomerations is prevented by this.

For the aforementioned purpose, the liquid mixture and the water be combined with each other, so it can be a mixture of solvents, surface-active Substance and water are introduced into the borehole. The relative amounts of solvent and surfactant may be as described above; however can larger amounts of surfactant can also be used, e.g. B. so much such as about 65 weight percent based on the solvent, or if a mixture is used the solvent and water. The water can be in the mix Solvent, surfactant and water as much as 75 percent by volume make up of solvent and water.

The following examples serve to further illustrate the Invention.

Example 1 The production from a gas well decreased steadily due to the accumulation of wax within the riser pipes. In the end, the well reached a production of 5910 Nm3 gas per day. At that time the well was taken out of service. In 1591 a liquid mixture of toluene and polyoxyethylene ether of nonylphenol, which contained an average of 30 moles of ethylene oxide in the oxyethylene chain, was introduced through the riser pipes into the borehole. The polyoxyethylene ether of nonylphenol constituted 5 percent by weight of the liquid mixture. The well was then closed over a period of 8 hours. A small amount of gas production from the well was then started to induce movement of the liquid mixture. After about an hour of this type of movement, the well was closed again. Then 318 l of water containing polyoxyethylene ether of nonylphenol with an average of 30 moles of ethylene oxide in the oxyethylene chain were introduced through the casing pipes and brought into contact with the accumulation of wax. The water contained 5 percent by weight of the ether. A small amount of gas was produced for about half an hour to agitate the mixture of water and surfactant in contact with the wax. After that, full production was made through the risers to blow off the well. In doing so, the wellbore produced a foamy liquid that comprised solvent and surfactant, water and surfactant, and emulsified wax.

The working stages of introducing 159 1 liquid mixture from the hydrocarbon solvent and the surfactant the risers, moving by slow production of gas, introducing 3181 water and surfactant, by slow production of gas and movement Blowing off the risers was repeated twice. With every blow-off occurred a foamy liquid that contains the solvent and surfactant, Included water and surfactant and emulsified wax. The third Blow off, however, was the amount of emulsified wax in the liquid considerably less than in the liquids discharged in the first and second blowdowns. After the third blow, the well was put into production and produced 14,000 Nm3 gas per day, i.e. H. more than twice as much as before the removal of the Wax buildup.

Example 2 A gas well produced 670 Nm3 of gas per day, but was the potential of this well was higher and the low production was due to accumulation of heavy hydrocarbons in the well. The well was in the first stage treated by 1591 a liquid mixture of toluene and 5 percent by weight Polyoxyethylene ether of nonylphenol (on average 30 moles of ethylene oxide in the oxyethylene chain) were brought down through the riser pipes. After about 1/2 hour touching the liquid mixture with the accumulation of heavy hydrocarbons were 3181 Water containing 5 percent by weight of polyoxyethylene ether of nonylphenol (on average 30 Mol of ethylene oxide in the oxyethylene chain), brought down through the riser pipes. The borehole was blown off half an hour later to remove the mixture of toluene and surfactant, water and surfactant and emulsified remove heavy hydrocarbons. The same treatment was repeated once. When blown off after the second treatment contained the one emerging from the borehole Liquid only slightly emulsified heavy hydrocarbons. The borehole was then put into production, and the production was 53,700 Nm3 gas per day.

The well maintained a gas production of 53,700 Nm3 per day for a short time and then gradually decreased from 10 750 Nm3 of gas per day, indicating an accumulation of heavy hydrocarbons within the wellbore. When this latter rate of production was reached, daily through the annulus between the risers and the casing pipes about 1 liter (one quart) of a liquid Mixture introduced into the wellbore consisting of 61.5 percent by weight polyoxyethylene ether Nonylphenol, which contained an average of 30 moles of ethylene oxide in the oxyethylene chain, 10 weight percent methanol and 28.5 weight percent water. The production increased to 21500 Nm3 per day and remained with daily introduction of the liquid mixture on this value. The well was subsequently drilled over a period of approximately one month Decommissioned month. When the well put back into production was the daily treatment changed to 18.91 following a mixture Composition introduced into the wellbore: 12.11 one by sulfur @ dioxy extraction aromatic oil obtained from kerosene, 7.57 liters of isopropyl alcohol, 0.38 liters of water and 500 g of polyoxyethylene ether of nonylphenol, which has an average of 30 moles of ethylene oxide contained in the oxyethylene chain. This mixture had a cloud point of about -7 ° C, @ so that they can also be handled satisfactorily during the winter months could. The mean production from the well with this treatment was approximately 32,000 Nm3 per day.

Claims (6)

Claims: 1. A method for cleaning a borehole that contains an accumulation of heavy hydrocarbons, thereby .g e k e n n -z e i c h n e t that in a two-stage working method, the accumulation is initially in a known manner with a liquid mixture that is a solvent for which comprises hydrocarbons and a surfactant, treated and then brings it into contact with water. 2. The method according to claim 1, characterized in that that in a known manner mixed with a surface-active substance Water is applied. 3. The method according to claim 1 or 2, characterized in that that both the solvent and then the water are moved while they are in contact with the hydrocarbon pool. 4. Procedure according to one of claims 1 to 3, characterized in that the solvent Toluene, xylene or benzene is used. 5. The method according to any one of the claims 1 to 4, characterized in that both the solvent and the water a non-ionic surfactant, e.g. B. polyoxyethylene ether, in one Amount of at least 0.1 percent by weight is added. 6. Procedure after a of claims 1 to 5, characterized in that the hydrocarbon accumulation alternately and optionally periodically with the solvent and the water in Brings touch. Documents considered: German Auslegeschrift No. 1018 006; U.S. Patent No. 2,818,079.