DE2243192A1 - METHOD OF FILLING WATER DRILLING HOLES WITH EXPLOSIVES - Google Patents

Description

OZ 72082

DYNAMIT NOBEL AKTIENGESELLSCHAFT
Troisdorf district Cologne

Method for filling water-bearing boreholes "with explosives

The present invention relates to a method of filling water-bearing boreholes with explosives.

It is known that powdered ammonium nitrate explosives in an unpatronized state can be blown into boreholes by means of compressed air
there is no further flow of water in the area of the borehole. If these circumstances are not taken into account, the results of the blasting work must be expected to be inadequate. Before the
Blowing unpatronized explosives into water-containing boreholes was therefore repeatedly warned. It was therefore forced to use so-called slurries for filling water-carrying boreholes with unpatronized explosives * However, without special measures, these water-containing mixtures have a lower detonation capacity than the anhydrous mixture. The weight-related work capacity of the water-containing mixture is also considerably lower than that of the water- »
free mix.

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The object was therefore to find a method with which it is possible to also drill holes with unpatronized water-bearing holes to fill powdered explosives.

The invention solves this problem. It consists of a procedure for filling water-bearing boreholes with explosives, which is characterized in that it is known per se powdered ammonium nitrate explosives, the swelling agents and / or contain water repellants, unpatronized by means of compressed air from a pressure vessel via one with its mouth brings up into the deepest borehole guided hose, which is intermittently or during the filling process from the borehole is continuously withdrawn that its mouth is below the by the compressed air at least substantially in Direction of the borehole entrance pushed back water and up to 50 cm, preferably up to 10 cm, above the surface of the filled explosives is located. The amount of air escaping with the explosive from the hose mouth when blowing in leads in an advantageous manner practically to a separation between explosives and water cover. The inventive method can therefore easily be applied even to boreholes completely filled with water. Are particularly advantageous the high degree of filling of the explosive in the borehole and the low technical effort required for a good blasting performance is.

The retraction of the hose is part of the method of the invention easy and simple to carry out, since the loading

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As a result of the slight vibrations of the hose and the explosive flowing through it, the service personnel can easily feel whether the explosive is still flowing properly or whether the flowing through The amount becomes smaller because the explosive rising in the borehole comes too close to the mouth of the hose and thus the outlet of the explosives to be blown out of the hose. In the latter case, the hose simply becomes a corresponding one Piece pulled out so that the explosive flows properly again. It is easily possible to find the perfect To monitor the flow of material in the hose by suitable automatically acting aids, for example by means of an am Hose arranged microphone, which is a device for self-employed Pulling out the hose controls.

The ammonium nitrate can go through up to a proportion of 50 Gev /.-% other oxygen-releasing salts are replaced, such as nitrates or perchlorates of the alkali or alkaline earth metals. These oxygen-releasing salts "should" just like the ammonium nitrate present in a grain shape and grain fineness that ensure easy blowing.

As water repellants, for example, polyvalent salts of long-chain fatty acids and / or long-chain fatty amines or their Called salts. The term long-chain is intended to mean that the number of carbon atoms in the chains is between 8 and 24.

Examples of swelling agents are water-soluble high polymers such as polyacrylamide, polyacrylic acid and their salts and polyvinylal-

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alcohol. However, polysaccharides are primarily suitable as swelling agents such as agar-agar, carboxymethyl cellulose, guar flour or the like.

Lubricants such as graphite or molybdenum disulfide can also be added to the explosive. The ammonium explosives mentioned may contain combustible substances, e.g. mineral or diesel oil, nitrotoluenes, coal dust, glycol, brain matter, Wood or vegetable flour. They can also use metallic fuels such as aluminum, magnesium or alloys of these Art included.

The ammonium nitrate explosives mentioned are as such, according to the type and amount of their composition, for use in cartridge form already known. In addition to the action of the swelling and / or hydrophilicizing agents, the cartridge case provided essential protection against the penetration of water into the explosive. The use of the cartridge case made it possible to use it at all of powdered ammonium nitrate explosives in water-bearing boreholes. However, it has the disadvantage that none complete filling or utilization of the borehole volume with explosives can be achieved «

It has been found in the method according to the present invention Proven to be beneficial in terms of economy, behavior towards water and the performance of the explosives, To use explosives, which consist of 60 to 98 wt .-% ammonium ni-

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and 2 to 40% by weight of combustibles exist, whereby in the combustible materials up to 10% by weight (on the explosives based) swelling agent and / or up to 3 wt .-% (on the Related to explosives) hydrophobizing agents are included.

It has been found that when using ammonium nitrate in prilled Shape the blowing ability, is good, the water absorption but does not satisfy under all circumstances. With the sole use of ammonium nitrate in ground form, the Water absorption is low, but when blowing in it can lead to irregularities in the transport of the explosive through the hose come. It has therefore proven to be advantageous if, according to a further proposal of the invention, the ammonium nitrate components of explosives in both priliter and gemalilener Form, preferably in a weight ratio of 2: 1. Prills from the range of the sieve mesh size of 0.2 to 20 mm, preferably 0.2 to 6 mm, in particular 0.8 to 2.5 mm can be used.

For blowing into boreholes, the last piece of the blowing hose can also be replaced by a pipe. At the end of Hose or pipe can also be made laterally holes so that some of the air escapes through them and the Displacement of the water favors. A ring-shaped bead can also be attached to the outside of the hose end Pushing the hose out of the borehole durcia, supported by the filled explosives and, on the other hand, as a result of the higher flow velocity of the inlet air between d © a

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Bead and the borehole wall also displace the water favored.

It was also found that an increase in the injection pressure up to about 4 kp / cm leads to a reduction in the water absorption of the explosive to be blown. When working with higher Blow presses are not used in the usual applications Weight-decreasing further advantages are achieved, but such a way of working is also feasible.

You can work in the method according to the invention so that in the pressure vessel below a richer in energy and above a lower-energy explosive is filled in, so that when the pressure vessel is emptied from below in the deepest of the borehole stronger and in the overlying part a weaker explosive is loaded.

If it is desired in the individual case, that the lower end the column of explosives in the borehole is as free of water as possible according to another proposal of the invention immediately before the start of the introduction of explosives through the hose through air be directed into the deepest part of the borehole in order to minimize the water present there before the explosives are introduced to displace. The additional air required for this is fed into the hose at a suitable point from the side.

Example 1:

An explosives mixture of the following ingredients was used for the experiment

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composition used:

prilled 55 wt .- # (90 wt. % grain size between 0.8 and.

2.5 mm, the rest smaller than 0.8 mm)

^^ ground 30 wt.

Aluminum powder 10% by weight

Mineral oil 2 wt .- #

Calcium stearate 1% by weight

Guar flour 2% by weight. ·.

This mixture was injected via a 6 m long injection hose from 25 mm inside diameter from a pressure vessel charger into a 4.50 m long, water-filled, vertical pipe with 80 mm inside diameter blown in. The lower part of the tube consisted of a 2 m long, crystal-clear piece for observation of the loading result. The working pressure in the pressure vessel was 3 kp / cm. At this pressure one reached in the charging hose a volume ratio between solid and air (converted to a pressure of 1 kp / cm) of 1: 2 to 1: 3.

When blowing in, it is necessary that the blowing hose is withdrawn to the extent that the borehole with explosives fills. When the injection material has risen so far in the borehole that it reaches the opening of the blow tube, a further outflow from the hose mouth stopped. The blower tube is then gradually pulled out so that there is again a distance to the column of material and so that the hose mouth is released again. Now konirr: τ the flow of material in the hose starts again and the filling

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continues until the column of explosives again reaches the mouth of the hose. A column 110 cm in length was placed in the tube, which was left under a column of water 1 m in length for 20 hours. No further water absorption by the explosive was observed. After this period of time, the explosive column had a moisture distribution as follows: At its lowest point, ie in the area where the blowing in began, there was a 10 cm long stopper with 22 % water content. This was followed by the main column with a length of 90 cm, which was produced by continuous blowing in, with a water content of 4 %. A 10 cm long, wet plug with a water content of 16% was located between this comparatively dry section of the charging station and the superimposed remaining water column.

When used in the borehole, the comparatively dry explosives zone forms practically the entire charging station and the short, Wet sections at both ends of the charging station no longer play a role in relation to the total mass of explosives.

The explosive detonated with 4 % water content in a steel tube of 52 mm inner diameter, 4 mm wall thickness and 450 mm length after ignition by means of a booster charge consisting of 27 g of pentaerythritol tetranitrate and 3 g of wax (density 1.5 g / cm) by. A plug intentionally stored temporarily with 20 % water content and 50 mm length or 13 % water content and 100 mm length was bridged by the detonation.

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The same mixture of explosives was also discharged from the pressure vessel charger via a 23 m long hose with an internal diameter of 25 mm blown into a 13.5 m long, water-filled pipe, the axis of which deviated from the vertical by 35 ° (inclined). The inside diameter was again 80 mm. The lower end of the tube was transparent again. The working pressure in the pressure vessel was 4 kg / cm. In this example, at the beginning of the injection hose In addition, some compressed air was blown in behind the charger to further loosen the material to be transported in the hose. ' This achieved a volume ratio between cargo and air of 1 in the loading hose; 4 to 1: 5.

In a procedure as in Example 1, the blowing in proceeded smoothly. If this additional air was used and it was introduced into the charging hose before the actual lock on the compressed air charger was opened, the water in the deepest part of the borehole was partially displaced before the explosive escaped from the charging hose. Thereby accounted for the ca _e 100 mm long wet explosives plug in the bottom of the hole. The continuously charged charging station had only absorbed a moisture of 1 to 3% in this test. Between this comparatively dry column of explosives and the overlying water there was again a more soaked layer of explosives 100 to 200 mm in length.

Example 2:

An explosives mixture of the following composition is used:

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- ίο -

prilled 60 wt-96 (90 wt-tf grain size between 0 * 8

and 2.5 mm, the rest smaller than 0.8 mm)

ground 34 parts by weight

Mineral oil 3 wt. Si

Calcium stearate 1 wt ..- Si

Guar flour 2% by weight

Such a mixture comes into question when an explosive is desired which is not as high in energy as that mentioned in Example 1.

When blowing with 4 kp / cm blowing pressure into the water-filled, vertical 6 m long pipe described in Example 1, the explosive in the middle part of the charging column absorbed 6 % water. During the experiment, such a mixture with 6% water content detonated perfectly in the steel pipe described in Example 1. If the water content was increased to 8% on a trial basis, the mixture in the steel pipe also detonated.

Example 3:

An explosives mixture of the following composition was used:

NHi ₁ NO, prilled 55.5 % by weight (90% by weight Si grain size between 0.8 ^H - * and 2.5 mm, the remainder smaller than 0.8 mm)

^NH 4 ^N0 3 milled 31.0 wt -.%
Aluminum powder 5.0 wt. 96
Dinitrotoluene 5.0 wt .- #

Calcium stearate 0.5 wt .- #

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Guar gum 1.0 wt -.%
Coal dust 2.0 wt -.%

The dinitrotoluene consisted of an isomer mixture that was still liquid ^{at 0 ° C.} '

Tested in the same way as in Example 2, the mixture took up 4.5 % water when it was blown into the central part of the charging column. When tested in the steel pipe, the mixture detonated perfectly. If the water content was intentionally increased to 8 % here as well, the mixture in the steel pipe was also detonative.

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Claims (5)

2 2 i - ^! υ 2 IX Patent claims: 1 _# method for filling water-carrying boreholes with explosives, characterized in that known powdered ammonium nitrate explosives containing swelling agents and / or hydrophobing agents are introduced unpatronized by means of compressed air from a pressure vessel via a hose with its mouth extending into the depth of the Bochloch is withdrawn during the filling process from the borehole in such a way intermittently or continuously that its mouth is below the water pushed back by the compressed air at least substantially in the direction of the borehole entrance and up to 50 cm, preferably up to 10 cm, above the surface of the filled explosive . 2. The method according to claim 1, characterized in that the explosives from 60 to 98 wt.% Ammonium nitrate and 2 to 40% by weight of combustible materials exist. Wherein in the combustible substances up to 10 wt.% (Based on the explosive) swelling agent and / or up to 3 wt. # (based on the explosive) hydrophobizing agents are included. 3. The method according to claim 1 and 2, characterized in that the ammonium nitrate components of the explosives in both in prilled and ground form, preferably in a weight ratio of 2: 1. 4098 11/0673. ORIQINAt INSPEÖtÜ ' ⁰ JJ I. Ί 1 q? / 3 4. The method according to any one of claims 1 Ms 3, characterized in that that in the pressure vessel below a more energetic and above a lower energy explosive is filled so that when the pressure vessel is emptied from below into the A stronger explosive is loaded into the deepest part of the borehole and a weaker explosive in the part above it. 5. The method according to any one of claims 1 to 4, characterized in that that immediately before the start of the introduction of explosives through the hose, air into the deepest part of the borehole is directed. Troisdorf, August 28, 1972
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