DE4311843A1 - Method and device for cleaning borehole filters in liquid extraction bores - Google Patents

Description

The invention relates to a method and an apparatus for cleaning Borehole filters in liquid extraction holes.

For cleaning borehole filters from collating deposits, as well Loam and toning are known procedures in which the same is done with water or air is flushed, ultrasonic cleaning, chemical, done electrolytically or electromechanically.

All these known methods have the disadvantage that they are complex are and do not lead to the desired result.

The invention has as its object the disadvantages of the known methods and devices to avoid the procedural and to reduce device engineering effort and effectiveness increase.

According to the invention the object is achieved in that in the cavity of the Well filter pressure impulses by ignition and explosion of a Hydrogen-oxygen gas mixture using the known Combustion and detonation processes are triggered. The Hydrogen-oxygen gas mixture is converted to by electrolysis treated section of the filter immediately before the explosion. This makes safety requirements and simplification the process-specific equipment.

To the effectiveness of the extraction of the destroyed accumulating deposits to increase, is atomized water into the explosion products Sprayed at the time of their collapse.

Explosion products of the hydrogen-oxygen mixture are overheated Water vapors, which partially cool down as they expand and then flood back under the effect of hydrostatic pressure and until complete cooling and condensation a series of Perform pulsations.  

In order to concentrate the effect of the pressure impulses, the explosion zone of the hydrogen-oxygen gas mixture from above and below Rubber cuffs limited and with mechanical cleaning combined.

The technological sequence of the method according to the invention is designed as follows:

• - Mechanical cleaning of the inner surface of the filter by moving the Device along the filter,
• - Limitation of the processing area by rubber sleeves,
• Feeding a known reagent into the explosion chamber,
• - carrying out the electrolysis in the KOH solution,
• Feeding the gaseous electrolysis products into the explosion chamber,
• - Separation of the required hydrogen-oxygen gas mixture in the explosion chamber,
• Igniting the gas mixture in the combustion and detonation regime,
• - Injecting atomized water at the stage of collapse Explosion products,
• - Move the device to a new one Processing interval.

In order to achieve a combined impulse-reagent effect, the Explosion zone of the hydrogen-oxygen gas mixture a reagent fed.

The advantages of the method according to the invention described Methods that represent the state of the art exist

• - in the possibility of obtaining hydrogen and oxygen directly in the area of the filter to be treated,
• - in the ecological safety of the process, since the Explosion products of the hydrogen-oxygen gas mixture convert their condensation into water,  
• - In the for with this method and the device according to the invention working voltages that are harmless when working Electrolysis of the hydrogen-oxygen gas mixture are required
• - In the nature of the reaction of the hydrogen-oxygen gas mixture its ignition, which is an explosion and subsequent implosion of this Mixture corresponds to
• - in the combination of the reaction of the hydrogen-oxygen gas mixture with a reagent effect that the contact surface of the colmatant with the Reagent increased and the solution of the deposits increased. For A reagent of known type is used, which is used, for example water extraction is suitable for drinking water.

The reaction of the hydrogen-oxygen gas mixture proceeds as Incineration and detonation.

The starting material for the electrolysis of water is a 20-30% concentrated alkaline KOH solution. A DC voltage is applied to the solution dipped electrodes, the water disintegrates under the effect of the electric current in hydrogen and oxygen:

2 H₂O ↔ 2 H₂ + O₂.

The normal combustion rate of the gas mixture is 2 H₂O₂ 34 m / s.

For an approximation of the combustion pressure in one closed space becomes the formula

p _a = P _o · (V₀ / V₁) (T₁ / T₀)

used, where
p _a - pressure in the implosion chamber,
V₀ - volume of the gaseous reaction products under normal conditions
V₁ - volume occupied by the gas mixture,
T₀ - gas temperature,
T₁ - achievable combustion temperature (approx. 4000 ° C)
are.

In the following, the method according to the invention is illustrated using an example are explained.

If a value of V₀ = 1244 dm³ / kg and V₁ = 1860 dm³ / kg is used, a combustion pressure of the gas mixture in the closed implosion chamber can be achieved under normal conditions of 1 MPa. This results in the combustion pressure p _a ≈ 10 p _abs , where p _{abs is} the absolute pressure of the mixture before the explosion. If the mixture is exploded in a closed explosion chamber at depth h below the water surface, then p _abs = p₀ + ϑ gh, where ϑ is the water density, and g is the speed of free fall. In this case the combustion pressure in the working chamber is at depth h

P _g = 10 (p₀ + ϑ gh).

Thus, at depth h = 10 m, the pressure is p _g ≈ 2 MPa, at h = 20 m the pressure is p _g ≈ 3 MPa, etc.

The combustion reaction of the hydrogen is 2 H₂ + 2 O₂ for the mixture through the equation

2 H₂O + 2 O₂ = 2 H₂O + 115 kcal

described.

From the equation follows that when burning 1 dm³ gas mixture under Normal conditions 7.1 kJ of energy are released. The combustion can caused by glowing wire and sparks.

The combustion can be used to regenerate borehole filters, which are clogged by loose, collating deposits, one have low strength. The explosion of hydrogen in the Detonation process takes place according to the reaction equation:

2 H₂ + 2 O₂ = 1.54 H₂O + 0.33 H₂ + 0.23 O₂ + 0.26 H + 75 kcal.

According to the reaction equation, when detonating 1 dm³ of the mixture 2 H₂ + 2 O₂ (under normal conditions) 4.64 kJ energy is released. The detonation creates a pressure wave that is broken in the water and can reach the filter. The pressure of the broken wave P _ud is approximately equal to p _ud = 7.2 p _g .

Despite the considerable amplitude, the pressure wave is very short and transfers a small part of the explosion energy. The main part of the The total energy of the explosion is the kinetic energy of the liquid the accumulating deposits are destroyed and washed away.

The detonation can be used to work in boreholes that pass through solid conglomerate-shaped deposits are collated.

The known devices for cleaning borehole filters cumulating deposits, as well as loam and clay correspond to each their aforementioned known methods, and therefore differ fundamentally of the device according to the invention, so that a Differentiation from the state of the art through the novelty of the process given is.

The device for cleaning borehole filters consists of a cylindrical dielectric housing, in the upper part of which Explosion chamber is located. At the top of this housing is a cylinder with the same longitudinal axis, but smaller diameter with the housing connected. An ignition device is attached in this part of the device which is preferably a spark plug. In the upper horizontal wall the explosion chamber, the supply of the reagent opens. The lower one The explosion chamber is delimited by a conical reflector formed with the cone tip facing upwards. At the level of the reflector outlet slots are provided in the outer wall of the device. Below of the reflector is the gas generator of the device. Of the Gas generator is with the explosion chamber through an additional chamber connected.  

The generated in the gas generator passes through a safety valve Explosive mixture in this chamber. One rigidly attached to the reflector Cone is by means of a bellows located under the cone with a connected to another movable cone. This cone has additional ones Water intake nozzles. There is a central one in the gas generator dielectric center rod. On this central rod are obliquely inclined elliptical electrodes attached, which within the Device housing are coated. Between this coat and Narrow feedthroughs are arranged on the electrodes. Upper and lower are located on the outer wall of the Housing rubber sleeves, at the lower end of the outer wall of the Housings are attached around the diameter brushes. The lower The end of the housing is closed by a base plate in which an outlet opening is attached.

In the following, the device is to be explained using an exemplary embodiment are explained.

Fig. 1 shows the device according to the invention in the borehole; Fig. 2 shows the device according to the invention in section.

By means of the lifting device 4 ( Fig. 1), the device for cleaning borehole filters 1 is lowered over the guide roller 5 on the cable into the area of the filter to be processed in such a way that the device already makes several up and down movements along the entire filter surface, thereby a partial mechanical cleaning of the inner filter surface is achieved by the brushes 32 ( FIG. 2). A direct voltage is passed via lines 34 and 35 to the electrodes 27 of the device. The reagent passes through the hose 33 into the explosion chamber 8 and partly spreads through the outlet slots 9 into the zone near the filter. After the gas generator 14 is filled with an alkaline solution, the electrolysis begins. The decay products carbon and hydrogen that arise between the electrodes 27 pass through the passage 28 between the electrodes 27 and the cylindrical jacket 29 to the overflow valve 17 . If the pressure is sufficient, this valve opens and the gas mixture passes through the chamber 16 into the explosion chamber 8 . After reaching a certain gas volume in the explosion chamber 8 , the gas mixture is made to explode by means of the ignition devices 11 and 12 .

The resulting pressure wave is reflected by the reflector 7 and directed to the filter. The flowing liquid acts on the movable cone 20 and moves it downwards. The bellows 19 held by the immobile cone 18 is pulled apart. An additional amount of water is drawn through the nozzles 21 . After the explosion products expand, they collapse, which creates a strong negative pressure in the filter area. As a result, the movable cone 20 moves upward and compresses the bellows 19 . The bellows 19 acts on the liquid in it in such a way that they are expelled in a finely atomized form through the nozzles 21 into the explosion products. The occurrence of water dust in the explosion products accelerates condensation and ensures the enlargement of the second pressure peak, as well as the vacuum when collapsing.

Since the reagent was in the filter cavity before igniting, the Kolmantant exposed to an impulse reagent effect. After every new one Impulse is the device for cleaning borehole filters to a new one Treatment interval advanced.

Reference list

1 device for cleaning borehole filters
2 DC voltage source
3 control panel
4 lifting device
5 leadership role
6 vial of reagent
7 reflector
8 explosion chamber
9 outlet slots
10 detonators
11 spark plug
12 filament
14 gas generator
1 5 Cover with overflow valve
1 6 safety lock
17 overflow valve
18 immovable cone
19 bellows
20 mov. cone
21 nozzles
22 dielectric housing
23 central rod
24 hole
25 drain plugs
26 filler plugs
27 electrodes, inclined
28 executions
29 cyl. coat
30 rubber sleeve
31 rubber sleeve
32 brushes
33 hose
34 line
35 line
36 line.

Claims (15)

1. A method for cleaning borehole filters in liquid extraction bores, characterized in that pressure impulses are generated in the filter cavity of the borehole filter, both by using combustion and detonation, by explosion of a hydrogen-oxygen gas mixture and solubilizing deposits are released. 2. The method according to claim 1, characterized in that the hydrogen Oxygen-gas mixture immediately before the explosion in the processing area the filter is obtained by electrolysis. 3. The method according to claim 1 and 2, characterized in that in the Explosion products of the hydrogen-oxygen gas mixture for Finely atomized water is injected at the time of their collapse. 4. The method according to claim 1 to 3, characterized in that the Effect of the pressure pulses on the section of the filter to be cleaned Sealing the explosion area of the hydrogen-oxygen Gas mixture is concentrated up and down. 5. The method according to claim 1 to 4, characterized in that in the Explosion zone of the hydrogen-oxygen gas mixture Deposits dissolving reagent is introduced. 6. The method according to claim 1 to 5, characterized in that the inner filter wall when introducing the device for performing the Process is cleaned mechanically. 7. Device for performing the method according to claims 1 to 6, characterized in that it consists of a dielectric housing with in its upper part arranged explosion chamber with ignition device and in the lower part arranged gas generator, and the Explosion chamber is separated from the gas generator by a reflector.   8. The device according to claim 7, characterized in that the Explosion chamber has a detonator. 9. The device according to claim 7 and 8, characterized in that the Gas generator designed as a bipolar electrolysis device and with one Water safety lock with overflow valves and centric arranged electrodes is provided. 10. The device according to claim 7 to 9, characterized in that the Electrodes are slanted. 11. The device according to claim 7 to 10, characterized in that the Electrodes have an elliptical or semi-elliptical shape. 12. The apparatus according to claim 7, characterized in that on the reflector centrically and rigidly an immobile cone is fixed over a bellows is connected to a movable cone, being on the outer surface of the immobile cone nozzles are arranged and the movable cone one has larger than the immobile cone. 13. The apparatus according to claim 7, characterized in that the Device above and below their explosion chamber Rubber sleeves is sealed. 14. The apparatus according to claim 7, characterized in that the Device has at its lower end one or more brush rings. 15. The apparatus according to claim 7, characterized in that on the Explosion chamber a hose for supplying the reagent is arranged.